History of science

The history of science covers the development of science from ancient times to the present. It encompasses all three major branches of science: natural, social, and formal.[1]

Science's earliest roots can be traced to Ancient Egypt and Mesopotamia around 3000 to 1200 BCE.[2][3] These civilizations' contributions to mathematics, astronomy, and medicine influenced later Greek natural philosophy of classical antiquity, wherein formal attempts were made to provide explanations of events in the physical world based on natural causes.[2][3] After the fall of the Western Roman Empire, knowledge of Greek conceptions of the world deteriorated in Latin-speaking Western Europe during the early centuries (400 to 1000 CE) of the Middle Ages,[4] but continued to thrive in the Greek-speaking Eastern Roman (or Byzantine) Empire. Aided by translations of Greek texts, the Hellenistic worldview was preserved and absorbed into the Arabic-speaking Muslim world during the Islamic Golden Age.[5] The recovery and assimilation of Greek works and Islamic inquiries into Western Europe from the 10th to 13th century revived the learning of natural philosophy in the West.[4][6]

Natural philosophy was transformed during the Scientific Revolution in 16th- to 17th-century Europe,[7][8][9] as new ideas and discoveries departed from previous Greek conceptions and traditions.[10][11][12][13] The New Science that emerged was more mechanistic in its worldview, more integrated with mathematics, and more reliable and open as its knowledge was based on a newly defined scientific method.[11][14][15] More "revolutions" in subsequent centuries soon followed. The chemical revolution of the 18th century, for instance, introduced new quantitative methods and measurements for chemistry.[16] In the 19th century, new perspectives regarding the conservation of energy, age of Earth, and evolution came into focus.[17][18][19][20][21][22] And in the 20th century, new discoveries in genetics and physics laid the foundations for new sub disciplines such as molecular biology and particle physics.[23][24] Moreover, industrial and military concerns as well as the increasing complexity of new research endeavors ushered in the era of "big science," particularly after the Second World War.[23][24][25]

Approaches to history of science

The nature of the history of science is a topic of debate (as is, by implication, the definition of science itself). The history of science is often seen as a linear story of progress[26] but historians have come to see the story as more complex.[27][28][29] Alfred Edward Taylor has characterised lean periods in the advance of scientific discovery as "periodical bankruptcies of science".[30]

Science is a human activity, and scientific contributions have come from people from a wide range of different backgrounds and cultures. Historians of science increasingly see their field as part of a global history of exchange, conflict and collaboration.[31]

The relationship between science and religion has been variously characterized in terms of "conflict", "harmony", "complexity", and "mutual independence", among others. Events in Europe such as the Galileo affair of the early-17th century - associated with the scientific revolution and the Age of Enlightenment - led scholars such as John William Draper to postulate (c.1874) a conflict thesis, suggesting that religion and science have been in conflict methodologically, factually and politically throughout history. The "conflict thesis" has since lost favor among the majority of contemporary scientists and historians of science.[32][33][34] However, some contemporary philosophers and scientists, such as Richard Dawkins,[35] Lawrence Krauss, Peter Atkins, and Donald Prothero, still subscribe to this thesis.

Historians have emphasized that trust is necessary for agreement on claims about nature. In this light, the 1660 establishment of the Royal Society and its code of experiment – trustworthy because witnessed by its members – has become an important chapter in the historiography of science.[36] Many people in modern history (typically women and persons of color) were excluded from elite scientific communities and characterized by the science establishment as inferior. Historians in the 1980s and 1990s described the structural barriers to participation and began to recover the contributions of overlooked individuals.[37][38] Historians have also investigated the mundane practices of science such as fieldwork and specimen collection,[39] correspondence,[40] drawing,[41] record-keeping,[42] and the use of laboratory and field equipment.[43]

Prehistoric times

In prehistoric times, knowledge and technique were passed from generation to generation in an oral tradition. For instance, the domestication of maize for agriculture has been dated to about 9,000 years ago in southern Mexico, before the development of writing systems.[44][45][46] Similarly, archaeological evidence indicates the development of astronomical knowledge in preliterate societies.[47][48]

The oral tradition of preliterate societies had several features, the first of which was its fluidity.[2] New information was constantly absorbed and adjusted to new circumstances or community needs. There were no archives or reports. This fluidity was closely related to the practical need to explain and justify a present state of affairs.[2] Another feature was the tendency to describe the universe as just sky and earth, with a potential underworld. They were also prone to identify causes with beginnings, thereby providing a historical origin with an explanation. There was also a reliance on a "medicine man" or "wise woman" for healing, knowledge of divine or demonic causes of diseases, and in more extreme cases, for rituals such as exorcism, divination, songs, and incantations.[2] Finally, there was an inclination to unquestioningly accept explanations that might be deemed implausible in more modern times while at the same time not being aware that such credulous behaviors could have posed problems.[2]

The development of writing enabled humans to store and communicate knowledge across generations with much greater accuracy. Its invention was a prerequisite for the development of philosophy and later science in ancient times.[2] Moreover, the extent to which philosophy and science would flourish in ancient times depended on the efficiency of a writing system (e.g., use of alphabets).[2]

Earliest roots

The earliest roots of science can be traced to Ancient Egypt and Mesopotamia in around 3000 to 1200 BCE.[2]

Ancient Egypt

Number system and geometry

Starting in around 3000 BCE, the ancient Egyptians developed a numbering system that was decimal in character and had oriented their knowledge of geometry to solving practical problems such as those of surveyors and builders.[2] Their development of geometry was itself a necessary development of surveying to preserve the layout and ownership of farmland, which was flooded annually by the Nile river. The 3-4-5 right triangle and other rules of geometry were used to build rectilinear structures, and the post and lintel architecture of Egypt.

Disease and healing

The Ebers Papyrus (c. 1550 BCE) from ancient Egypt

Egypt was also a center of alchemy research for much of the Mediterranean. Based on the medical papyri written in the 2500–1200 BCE, the ancient Egyptians believed that disease was mainly caused by the invasion of bodies by evil forces or spirits.[2] Thus, in addition to using medicines, their healing therapies included prayer, incantation, and ritual.[2] The Ebers Papyrus, written in around 1600 BCE, contains medical recipes for treating diseases related to the eyes, mouth, skin, internal organs, and extremities, as well as abscesses, wounds, burns, ulcers, swollen glands, tumors, headaches, and even bad breath. The Edwin Smith papyrus, written at about the same time, contains a surgical manual for treating wounds, fractures, and dislocations. The Egyptians believed that the effectiveness of their medicines depended on the preparation and administration under appropriate rituals.[2] Medical historians believe that ancient Egyptian pharmacology, for example, was largely ineffective.[49] Both the Ebers and Edwin Smith papyri applied the following components to the treatment of disease: examination, diagnosis, treatment, and prognosis,[50] which display strong parallels to the basic empirical method of science and, according to G.E.R. Lloyd,[51] played a significant role in the development of this methodology.

Calendar

The ancient Egyptians even developed an official calendar that contained twelve months, thirty days each, and five days at the end of the year.[2] Unlike the Babylonian calendar or the ones used in Greek city-states at the time, the official Egyptian calendar was much simpler as it was fixed and did not take lunar and solar cycles into consideration.[2]

Mesopotamia

Clay models of animal livers dating between the nineteenth and eighteenth centuries BCE, found in the royal palace at Mari in what is now Syria

The ancient Mesopotamians had extensive knowledge about the chemical properties of clay, sand, metal ore, bitumen, stone, and other natural materials, and applied this knowledge to practical use in manufacturing pottery, faience, glass, soap, metals, lime plaster, and waterproofing. Metallurgy required knowledge about the properties of metals. Nonetheless, the Mesopotamians seem to have had little interest in gathering information about the natural world for the mere sake of gathering information and were far more interested in studying the manner in which the gods had ordered the universe. Biology of non-human organisms was generally only written about in the context of mainstream academic disciplines. Animal physiology was studied extensively for the purpose of divination; the anatomy of the liver, which was seen as an important organ in haruspicy, was studied in particularly intensive detail. Animal behavior was also studied for divinatory purposes. Most information about the training and domestication of animals was probably transmitted orally without being written down, but one text dealing with the training of horses has survived.[52]

Mesopotamian medicine

The ancient Mesopotamians had no distinction between "rational science" and magic.[53][54][55] When a person became ill, doctors prescribed magical formulas to be recited as well as medicinal treatments.[53][54][55][52] The earliest medical prescriptions appear in Sumerian during the Third Dynasty of Ur (c. 2112 BCE – c. 2004 BCE).[56] The most extensive Babylonian medical text, however, is the Diagnostic Handbook written by the ummânū, or chief scholar, Esagil-kin-apli of Borsippa,[57] during the reign of the Babylonian king Adad-apla-iddina (1069–1046 BCE).[58] In East Semitic cultures, the main medicinal authority was a kind of exorcist-healer known as an āšipu.[53][54][55] The profession was generally passed down from father to son and was held in extremely high regard.[53] Of less frequent recourse was another kind of healer known as an asu, who corresponds more closely to a modern physician and treated physical symptoms using primarily folk remedies composed of various herbs, animal products, and minerals, as well as potions, enemas, and ointments or poultices. These physicians, who could be either male or female, also dressed wounds, set limbs, and performed simple surgeries. The ancient Mesopotamians also practiced prophylaxis and took measures to prevent the spread of disease.[52]

Astronomy and celestial divination

Star list with distance information, Uruk (Iraq), 320-150 BCE, the list gives each constellation, the number of stars and the distance information to the next constellation in ells

In Babylonian astronomy, records of the motions of the stars, planets, and the moon are left on thousands of clay tablets created by scribes. Even today, astronomical periods identified by Mesopotamian proto-scientists are still widely used in Western calendars such as the solar year and the lunar month. Using this data, they developed mathematical methods to compute the changing length of daylight in the course of the year, predict the appearances and disappearances of the Moon and planets, and eclipses of the Sun and Moon. Only a few astronomers' names are known, such as that of Kidinnu, a Chaldean astronomer and mathematician. Kiddinu's value for the solar year is in use for today's calendars. Babylonian astronomy was "the first and highly successful attempt at giving a refined mathematical description of astronomical phenomena." According to the historian A. Aaboe, "all subsequent varieties of scientific astronomy, in the Hellenistic world, in India, in Islam, and in the West—if not indeed all subsequent endeavour in the exact sciences—depend upon Babylonian astronomy in decisive and fundamental ways."[59]

To the Babylonians and other Near Eastern cultures, messages from the gods or omens were concealed in all natural phenomena that could be deciphered and interpreted by those who are adept.[2] Hence, it was believed that the gods could speak through all terrestrial objects (e.g., animal entrails, dreams, malformed births, or even the color of a dog urinating on a person) and celestial phenomena.[2] Moreover, Babylonian astrology was inseparable from Babylonian astronomy.

Mathematics

The Mesopotamian cuneiform tablet Plimpton 322, dating to the eighteenth-century BCE, records a number of Pythagorean triplets (3,4,5) (5,12,13) ...,[60] hinting that the ancient Mesopotamians might have been aware of the Pythagorean theorem over a millennium before Pythagoras.[61][62][63]

Ancient Asia

Mathematical achievements from Mesopotamia had some influence on the development of mathematics in India, and there were confirmed transmissions of mathematical ideas between India and China, which were bidirectional.[64] Nevertheless, the mathematical and scientific achievements in India and particularly in China occurred largely independently[65] from those of Europe and the confirmed early influences that these two civilizations had on the development of science in Europe in the pre-modern era were indirect, with Mesopotamia and later the Islamic World acting as intermediaries.[64] The arrival of modern science, which grew out of the Scientific Revolution, in India and China and the greater Asian region in general can be traced to the scientific activities of Jesuit missionaries who were interested in studying the region's flora and fauna during the 16th to 17th century.[66]

India

Ancient India was an early leader in metallurgy, as evidenced by the wrought-iron Pillar of Delhi.

Indian astronomy and mathematics

The earliest traces of mathematical knowledge in the Indian subcontinent appear with the Indus Valley Civilisation (c. 4th millennium BCE ~ c. 3rd millennium BCE). The people of this civilization made bricks whose dimensions were in the proportion 4:2:1, which is favorable for the stability of a brick structure.[67] They also tried to standardize measurement of length to a high degree of accuracy. They designed a ruler—the Mohenjo-daro ruler—whose unit of length (approximately 1.32 inches or 3.4 centimetres) was divided into ten equal parts. Bricks manufactured in ancient Mohenjo-daro often had dimensions that were integral multiples of this unit of length.[68]

Indian astronomer and mathematician Aryabhata (476–550), in his Aryabhatiya (499) introduced the sine function in trigonometry and the number 0 [mathmatics] . In 628 CE, Brahmagupta suggested that gravity was a force of attraction.[69][70] He also lucidly explained the use of zero as both a placeholder and a decimal digit, along with the Hindu–Arabic numeral system now used universally throughout the world. Arabic translations of the two astronomers' texts were soon available in the Islamic world, introducing what would become Arabic numerals to the Islamic world by the 9th century.[71][72] During the 14th–16th centuries, the Kerala school of astronomy and mathematics made significant advances in astronomy and especially mathematics, including fields such as trigonometry and analysis. In particular, Madhava of Sangamagrama is considered the "founder of mathematical analysis".[73]

In the Tantrasangraha treatise, Nilakantha Somayaji's updated the Aryabhatan model for the interior planets, Mercury, and Venus and the equation that he specified for the center of these planets was more accurate than the ones in European or Islamic astronomy until the time of Johannes Kepler in the 17th century.[74]

The first textual mention of astronomical concepts comes from the Vedas, religious literature of India.[75] According to Sarma (2008): "One finds in the Rigveda intelligent speculations about the genesis of the universe from nonexistence, the configuration of the universe, the spherical self-supporting earth, and the year of 360 days divided into 12 equal parts of 30 days each with a periodical intercalary month.".[75] The first 12 chapters of the Siddhanta Shiromani, written by Bhāskara in the 12th century, cover topics such as: mean longitudes of the planets; true longitudes of the planets; the three problems of diurnal rotation; syzygies; lunar eclipses; solar eclipses; latitudes of the planets; risings and settings; the moon's crescent; conjunctions of the planets with each other; conjunctions of the planets with the fixed stars; and the patas of the sun and moon. The 13 chapters of the second part cover the nature of the sphere, as well as significant astronomical and trigonometric calculations based on it.

Grammar

Some of the earliest linguistic activities can be found in Iron Age India (1st millennium BCE) with the analysis of Sanskrit for the purpose of the correct recitation and interpretation of Vedic texts. The most notable grammarian of Sanskrit was Pāṇini (c. 520–460 BCE), whose grammar formulates close to 4,000 rules for Sanskrit. Inherent in his analytic approach are the concepts of the phoneme, the morpheme and the root. The Tolkāppiyam text, composed in the early centuries of the common era,[76] is a comprehensive text on Tamil grammar, which includes sutras on orthography, phonology, etymology, morphology, semantics, prosody, sentence structure and the significance of context in language.

Medicine

Findings from Neolithic graveyards in what is now Pakistan show evidence of proto-dentistry among an early farming culture.[77] The ancient text Suśrutasamhitā of Suśruta describes procedures on various forms of surgery, including rhinoplasty, the repair of torn ear lobes, perineal lithotomy, cataract surgery, and several other excisions and other surgical procedures.

Politics and state

An ancient Indian treatise on statecraft, economic policy and military strategy by Kautilya[78] and Viṣhṇugupta,[79] who are traditionally identified with Chāṇakya (c. 350–283 BCE). In this treatise, the behaviors and relationships of the people, the King, the State, the Government Superintendents, Courtiers, Enemies, Invaders, and Corporations are analyzed and documented. Roger Boesche describes the Arthaśāstra as "a book of political realism, a book analyzing how the political world does work and not very often stating how it ought to work, a book that frequently discloses to a king what calculating and sometimes brutal measures he must carry out to preserve the state and the common good."[80]

China

Lui Hui's Survey of sea island

Chinese mathematics

From the earliest the Chinese used a positional decimal system on counting boards in order to calculate. To express 10, a single rod is placed in the second box from the right. The spoken language uses a similar system to English: e.g. four thousand two hundred and seven. No symbol was used for zero. By the 1st century BCE, negative numbers and decimal fractions were in use and The Nine Chapters on the Mathematical Art included methods for extracting higher order roots by Horner's method and solving linear equations and by Pythagoras' theorem. Cubic equations were solved in the Tang dynasty and solutions of equations of order higher than 3 appeared in print in 1245 CE by Ch'in Chiu-shao. Pascal's triangle for binomial coefficients was described around 1100 by Jia Xian.

Although the first attempts at an axiomatization of geometry appear in the Mohist canon in 330 BCE, Liu Hui developed algebraic methods in geometry in the 3rd century CE and also calculated pi to 5 significant figures. In 480, Zu Chongzhi improved this by discovering the ratio which remained the most accurate value for 1200 years.

Astronomical observations

One of the star maps from Su Song's Xin Yi Xiang Fa Yao published in 1092, featuring a cylindrical projection similar to Mercator, and the corrected position of the pole star thanks to Shen Kuo's astronomical observations.[81]

Astronomical observations from China constitute the longest continuous sequence from any civilization and include records of sunspots (112 records from 364 BCE), supernovas (1054), lunar and solar eclipses. By the 12th century, they could reasonably accurately make predictions of eclipses, but the knowledge of this was lost during the Ming dynasty, so that the Jesuit Matteo Ricci gained much favor in 1601 by his predictions.[82] By 635 Chinese astronomers had observed that the tails of comets always point away from the sun.

From antiquity, the Chinese used an equatorial system for describing the skies and a star map from 940 was drawn using a cylindrical (Mercator) projection. The use of an armillary sphere is recorded from the 4th century BCE and a sphere permanently mounted in equatorial axis from 52 BCE. In 125 CE Zhang Heng used water power to rotate the sphere in real time. This included rings for the meridian and ecliptic. By 1270 they had incorporated the principles of the Arab torquetum.

In the Song Empire (960–1279) of Imperial China, Chinese scholar-officials unearthed, studied, and cataloged ancient artifacts.

Inventions

A modern replica of Han dynasty polymath scientist Zhang Heng's seismometer of 132 CE

To better prepare for calamities, Zhang Heng invented a seismometer in 132 CE which provided instant alert to authorities in the capital Luoyang that an earthquake had occurred in a location indicated by a specific cardinal or ordinal direction.[83][84] Although no tremors could be felt in the capital when Zhang told the court that an earthquake had just occurred in the northwest, a message came soon afterwards that an earthquake had indeed struck 400 to 500 km (250 to 310 mi) northwest of Luoyang (in what is now modern Gansu).[85] Zhang called his device the 'instrument for measuring the seasonal winds and the movements of the Earth' (Houfeng didong yi 候风地动仪), so-named because he and others thought that earthquakes were most likely caused by the enormous compression of trapped air.[86]

There are many notable contributors to early Chinese disciplines, inventions, and practices throughout the ages. One of the best examples would be the medieval Song Chinese Shen Kuo (1031–1095), a polymath and statesman who was the first to describe the magnetic-needle compass used for navigation, discovered the concept of true north, improved the design of the astronomical gnomon, armillary sphere, sight tube, and clepsydra, and described the use of drydocks to repair boats. After observing the natural process of the inundation of silt and the find of marine fossils in the Taihang Mountains (hundreds of miles from the Pacific Ocean), Shen Kuo devised a theory of land formation, or geomorphology. He also adopted a theory of gradual climate change in regions over time, after observing petrified bamboo found underground at Yan'an, Shaanxi province. If not for Shen Kuo's writing,[87] the architectural works of Yu Hao would be little known, along with the inventor of movable type printing, Bi Sheng (990–1051). Shen's contemporary Su Song (1020–1101) was also a brilliant polymath, an astronomer who created a celestial atlas of star maps, wrote a treatise related to botany, zoology, mineralogy, and metallurgy, and had erected a large astronomical clocktower in Kaifeng city in 1088. To operate the crowning armillary sphere, his clocktower featured an escapement mechanism and the world's oldest known use of an endless power-transmitting chain drive.[88]

The Jesuit China missions of the 16th and 17th centuries "learned to appreciate the scientific achievements of this ancient culture and made them known in Europe. Through their correspondence European scientists first learned about the Chinese science and culture."[89] Western academic thought on the history of Chinese technology and science was galvanized by the work of Joseph Needham and the Needham Research Institute. Among the technological accomplishments of China were, according to the British scholar Needham, early seismological detectors (Zhang Heng in the 2nd century), the water-powered celestial globe (Zhang Heng), matches, the independent invention of the decimal system, dry docks, sliding calipers, the double-action piston pump, cast iron, the blast furnace, the iron plough, the multi-tube seed drill, the wheelbarrow, the suspension bridge, the winnowing machine, the rotary fan, the parachute, natural gas as fuel, the raised-relief map, the propeller, the crossbow, and a solid fuel rocket, the multistage rocket, the horse collar, along with contributions in logic, astronomy, medicine, and other fields.

However, cultural factors prevented these Chinese achievements from developing into "modern science". According to Needham, it may have been the religious and philosophical framework of Chinese intellectuals which made them unable to accept the ideas of laws of nature:

It was not that there was no order in nature for the Chinese, but rather that it was not an order ordained by a rational personal being, and hence there was no conviction that rational personal beings would be able to spell out in their lesser earthly languages the divine code of laws which he had decreed aforetime. The Taoists, indeed, would have scorned such an idea as being too naïve for the subtlety and complexity of the universe as they intuited it.[90]

Classical antiquity

The contributions of the Ancient Egyptians and Mesopotamians in the areas of astronomy, mathematics, and medicine had entered and shaped Greek natural philosophy of classical antiquity, whereby formal attempts were made to provide explanations of events in the physical world based on natural causes.[2][3] Inquiries were also aimed at such practical goals such as establishing a reliable calendar or determining how to cure a variety of illnesses. The ancient people who were considered the first scientists may have thought of themselves as natural philosophers, as practitioners of a skilled profession (for example, physicians), or as followers of a religious tradition (for example, temple healers).

Pre-socratics

The earliest Greek philosophers, known as the pre-Socratics,[91] provided competing answers to the question found in the myths of their neighbors: "How did the ordered cosmos in which we live come to be?"[92] The pre-Socratic philosopher Thales (640–546 BCE) of Miletus, identified by later authors such as Aristotle as the first of the Ionian philosophers,[2] postulated non-supernatural explanations for natural phenomena. For example, that land floats on water and that earthquakes are caused by the agitation of the water upon which the land floats, rather than the god Poseidon.[93] Thales' student Pythagoras of Samos founded the Pythagorean school, which investigated mathematics for its own sake, and was the first to postulate that the Earth is spherical in shape.[94] Leucippus (5th century BCE) introduced atomism, the theory that all matter is made of indivisible, imperishable units called atoms. This was greatly expanded on by his pupil Democritus and later Epicurus.

Natural philosophy

Plato's Academy. 1st century mosaic from Pompeii

Plato and Aristotle produced the first systematic discussions of natural philosophy, which did much to shape later investigations of nature. Their development of deductive reasoning was of particular importance and usefulness to later scientific inquiry. Plato founded the Platonic Academy in 387 BCE, whose motto was "Let none unversed in geometry enter here," and also turned out many notable philosophers. Plato's student Aristotle introduced empiricism and the notion that universal truths can be arrived at via observation and induction, thereby laying the foundations of the scientific method.[95] Aristotle also produced many biological writings that were empirical in nature, focusing on biological causation and the diversity of life. He made countless observations of nature, especially the habits and attributes of plants and animals on Lesbos, classified more than 540 animal species, and dissected at least 50.[96] Aristotle's writings profoundly influenced subsequent Islamic and European scholarship, though they were eventually superseded in the Scientific Revolution.[97][98]

Aristotle also contributed to theories of the elements and the cosmos. He believed that the celestial bodies (such as the planets and the Sun) had something called an unmoved mover that put the celestial bodies in motion. Aristotle tried to explain everything through mathematics and physics, but sometimes explained things such as the motion of celestial bodies through a higher power such as God. Aristotle did not have the technological advancements that would have explained the motion of celestial bodies.[99] In addition, Aristotle had many views on the elements. He believed that everything was derived of the elements earth, water, air, fire, and lastly the Aether. The Aether was a celestial element, and therefore made up the matter of the celestial bodies.[100] The elements of earth, water, air and fire were derived of a combination of two of the characteristics of hot, wet, cold, and dry, and all had their inevitable place and motion. The motion of these elements begins with earth being the closest to "the Earth," then water, air, fire, and finally Aether. In addition to the makeup of all things, Aristotle came up with theories as to why things did not return to their natural motion. He understood that water sits above earth, air above water, and fire above air in their natural state. He explained that although all elements must return to their natural state, the human body and other living things have a constraint on the elements – thus not allowing the elements making one who they are to return to their natural state.[101]

The important legacy of this period included substantial advances in factual knowledge, especially in anatomy, zoology, botany, mineralogy, geography, mathematics and astronomy; an awareness of the importance of certain scientific problems, especially those related to the problem of change and its causes; and a recognition of the methodological importance of applying mathematics to natural phenomena and of undertaking empirical research.[102] In the Hellenistic age scholars frequently employed the principles developed in earlier Greek thought: the application of mathematics and deliberate empirical research, in their scientific investigations.[103] Thus, clear unbroken lines of influence lead from ancient Greek and Hellenistic philosophers, to medieval Muslim philosophers and scientists, to the European Renaissance and Enlightenment, to the secular sciences of the modern day. Neither reason nor inquiry began with the Ancient Greeks, but the Socratic method did, along with the idea of Forms, give great advances in geometry, logic, and the natural sciences. According to Benjamin Farrington, former professor of Classics at Swansea University:

"Men were weighing for thousands of years before Archimedes worked out the laws of equilibrium; they must have had practical and intuitional knowledge of the principals involved. What Archimedes did was to sort out the theoretical implications of this practical knowledge and present the resulting body of knowledge as a logically coherent system."

and again:

"With astonishment we find ourselves on the threshold of modern science. Nor should it be supposed that by some trick of translation the extracts have been given an air of modernity. Far from it. The vocabulary of these writings and their style are the source from which our own vocabulary and style have been derived."[104]

Greek astronomy

Schematic of the Antikythera mechanism (150–100 BCE).

The astronomer Aristarchus of Samos was the first known person to propose a heliocentric model of the Solar System, while the geographer Eratosthenes accurately calculated the circumference of the Earth. Hipparchus (c. 190 – c. 120 BCE) produced the first systematic star catalog. The level of achievement in Hellenistic astronomy and engineering is impressively shown by the Antikythera mechanism (150–100 BCE), an analog computer for calculating the position of planets. Technological artifacts of similar complexity did not reappear until the 14th century, when mechanical astronomical clocks appeared in Europe.[105]

Hellenistic medicine

There was not a defined societal structure for healthcare during the age of Hippocrates.[106] At that time, society was not organized and knowledgeable as people still relied on pure religious reasoning to explain illnesses.[106] Hippocrates introduced the first healthcare system based on science and clinical protocols.[107] Hippocrates' theories about physics and medicine helped pave the way in creating an organized medical structure for society.[107] In medicine, Hippocrates (c. 460 BC – c. 370 BCE) and his followers were the first to describe many diseases and medical conditions and developed the Hippocratic Oath for physicians, still relevant and in use today. Hippocrates' ideas are expressed in The Hippocratic Corpus. The collection notes descriptions of medical philosophies and how disease and lifestyle choices reflect on the physical body.[107] Hippocrates influenced a Westernized, professional relationship among physician and patient.[108] Hippocrates is also known as "the Father of Medicine".[107]Herophilos (335–280 BCE) was the first to base his conclusions on dissection of the human body and to describe the nervous system. Galen (129 – c. 200 CE) performed many audacious operations—including brain and eye surgeries— that were not tried again for almost two millennia.

Greek mathematics

One of the oldest surviving fragments of Euclid's Elements, found at Oxyrhynchus and dated to c. 100 CE.[109]
Archimedes used the method of exhaustion to approximate the value of π.

In Hellenistic Egypt, the mathematician Euclid laid down the foundations of mathematical rigor and introduced the concepts of definition, axiom, theorem and proof still in use today in his Elements, considered the most influential textbook ever written.[110] Archimedes, considered one of the greatest mathematicians of all time,[111] is credited with using the method of exhaustion to calculate the area under the arc of a parabola with the summation of an infinite series, and gave a remarkably accurate approximation of pi.[112] He is also known in physics for laying the foundations of hydrostatics, statics, and the explanation of the principle of the lever.

Other developments

Theophrastus wrote some of the earliest descriptions of plants and animals, establishing the first taxonomy and looking at minerals in terms of their properties such as hardness. Pliny the Elder produced what is one of the largest encyclopedias of the natural world in 77 CE and must be regarded as the rightful successor to Theophrastus. For example, he accurately describes the octahedral shape of the diamond and proceeded to mention that diamond dust is used by engravers to cut and polish other gems owing to its great hardness. His recognition of the importance of crystal shape is a precursor to modern crystallography, while mention of numerous other minerals presages mineralogy. He also recognizes that other minerals have characteristic crystal shapes, but in one example, confuses the crystal habit with the work of lapidaries. He was also the first to recognize that amber was a fossilized resin from pine trees because he had seen samples with trapped insects within them.

The development of the field of archaeology has its roots with history and with those who were interested in the past, such as kings and queens who wanted to show past glories of their respective nations. The 5th-century-BCE Greek historian Herodotus was the first scholar to systematically study the past and perhaps the first to examine artifacts.

Greek scholarship under Roman rule

During the rule of Rome, famous historians such as Polybius, Livy and Plutarch documented the rise of the Roman Republic, and the organization and histories of other nations, while statesmen like Julius Caesar, Cicero, and others provided examples of the politics of the republic and Rome's empire and wars. The study of politics during this age was oriented toward understanding history, understanding methods of governing, and describing the operation of governments.

The Roman conquest of Greece did not diminish learning and culture in the Greek provinces.[113] On the contrary, the appreciation of Greek achievements in literature, philosophy, politics, and the arts by Rome's upper class coincided with the increased prosperity of the Roman Empire. Greek settlements had existed in Italy for centuries and the ability to read and speak Greek was not uncommon in Italian cities such as Rome.[113] Moreover, the settlement of Greek scholars in Rome, whether voluntarily or as slaves, gave Romans access to teachers of Greek literature and philosophy. Conversely, young Roman scholars also studied abroad in Greece and upon their return to Rome, were able to convey Greek achievements to their Latin leadership.[113] And despite the translation of a few Greek texts into Latin, Roman scholars who aspired to the highest level did so using the Greek language. The Roman statesman and philosopher Cicero (106 – 43 BCE) was a prime example. He had studied under Greek teachers in Rome and then in Athens and Rhodes. He mastered considerable portions of Greek philosophy, wrote Latin treatises on several topics, and even wrote Greek commentaries of Plato's Timaeus as well as a Latin translation of it, which has not survived.[113]

In the beginning, support for scholarship in Greek knowledge was almost entirely funded by the Roman upper class.[113] There were all sorts of arrangements, ranging from a talented scholar being attached to a wealthy household to owning educated Greek-speaking slaves.[113] In exchange, scholars who succeeded at the highest level had an obligation to provide advice or intellectual companionship to their Roman benefactors, or to even take care of their libraries. The less fortunate or accomplished ones would teach their children or perform menial tasks.[113] The level of detail and sophistication of Greek knowledge was adjusted to suit the interests of their Roman patrons. That meant popularizing Greek knowledge by presenting information that were of practical value such as medicine or logic (for courts and politics) but excluding subtle details of Greek metaphysics and epistemology. Beyond the basics, the Romans did not value natural philosophy and considered it an amusement for leisure time.[113]

Commentaries and encyclopedias were the means by which Greek knowledge was popularized for Roman audiences.[113] The Greek scholar Posidonius (c. 135-c. 51 BCE), a native of Syria, wrote prolifically on history, geography, moral philosophy, and natural philosophy. He greatly influenced Latin writers such as Marcus Terentius Varro (116-27 BCE), who wrote the encyclopedia Nine Books of Disciplines, which covered nine arts: grammar, rhetoric, logic, arithmetic, geometry, astronomy, musical theory, medicine, and architecture.[113] The Disciplines became a model for subsequent Roman encyclopedias and Varro's nine liberal arts were considered suitable education for a Roman gentleman. The first seven of Varro's nine arts would later define the seven liberal arts of medieval schools.[113] The pinnacle of the popularization movement was the Roman scholar Pliny the Elder (23/24–79 CE), a native of northern Italy, who wrote several books on the history of Rome and grammar. His most famous work was his voluminous Natural History.[113]

After the death of the Roman Emperor Marcus Aurelius in 180 CE, the favorable conditions for scholarship and learning in the Roman Empire were upended by political unrest, civil war, urban decay, and looming economic crisis.[113] In around 250 CE, barbarians began attacking and invading the Roman frontiers. These combined events led to a general decline in political and economic conditions. The living standards of the Roman upper class was severely impacted, and their loss of leisure diminished scholarly pursuits.[113] Moreover, during the 3rd and 4th centuries CE, the Roman Empire was administratively divided into two halves: Greek East and Latin West. These administrative divisions weakened the intellectual contact between the two regions.[113] Eventually, both halves went their separate ways, with the Greek East becoming the Byzantine Empire.[113] Christianity was also steadily expanding during this time and soon became a major patron of education in the Latin West. Initially, the Christian church adopted some of the reasoning tools of Greek philosophy in the 2nd and 3rd centuries CE to defend its faith against sophisticated opponents.[113] Nevertheless, Greek philosophy received a mixed reception from leaders and adherents of the Christian faith.[113] Some such as Tertullian (c. 155-c. 230 CE) were vehemently opposed to philosophy, denouncing it as heretic. Others such as Augustine of Hippo (354-430 CE) were ambivalent and defended Greek philosophy and science as the best ways to understand the natural world and therefore treated it as a handmaiden (or servant) of religion.[113] Education in the West began its gradual decline, along with the rest of Western Roman Empire, due to invasions by Germanic tribes, civil unrest, and economic collapse. Contact with the classical tradition was lost in specific regions such as Roman Britain and northern Gaul but continued to exist in Rome, northern Italy, southern Gaul, Spain, and North Africa.[113]

Middle Ages

In the Middle Ages, the classical learning continued in three major linguistic cultures and civilizations: Greek (the Byzantine Empire), Arabic (the Islamic world), and Latin (Western Europe).

Byzantine Empire

The frontispiece of the Vienna Dioscurides, which shows a set of seven famous physicians

Preservation of Greek heritage

The fall of the Western Roman Empire led to a deterioration of the classical tradition in the western part (or Latin West) of Europe in the 400s. In contrast, the Eastern Roman or Byzantine Empire resisted the barbarian attacks and preserved and improved the learning.[114]

While the Byzantine Empire still held learning centers such as Constantinople, Alexandria and Antioch, Western Europe's knowledge was concentrated in monasteries until the development of medieval universities in the 12th centuries. The curriculum of monastic schools included the study of the few available ancient texts and of new works on practical subjects like medicine[115] and timekeeping.[116]

In the sixth century in the Byzantine Empire, Isidore of Miletus compiled Archimedes' mathematical works in the Archimedes Palimpsest, where all Archimedes' mathematical contributions were collected and studied.

John Philoponus, another Byzantine scholar, was the first to question Aristotle's teaching of physics, introducing the theory of impetus.[117][118] The theory of impetus was an auxiliary or secondary theory of Aristotelian dynamics, put forth initially to explain projectile motion against gravity. It is the intellectual precursor to the concepts of inertia, momentum and acceleration in classical mechanics.[119] The works of John Philoponus inspired Galileo Galilei ten centuries later.[120][121]

Collapse

During the Fall of Constantinople in 1453, a number of Greek scholars fled to North Italy in which they fueled the era later commonly known as the "Renaissance" as they brought with them a great deal of classical learning including an understanding of botany, medicine, and zoology. Byzantium also gave the West important inputs: John Philoponus' criticism of Aristotelian physics, and the works of Dioscorides.[122]

Islamic world

15th-century manuscript of Avicenna's The Canon of Medicine.

This was the period (8th–14th century CE) of the Islamic Golden Age where commerce thrived, and new ideas and technologies emerged such as the importation of papermaking from China, which made the copying of manuscripts inexpensive.

Translations and Hellenization

The eastward transmission of Greek heritage to Western Asia was a slow and gradual process that spanned over a thousand years, beginning with the Asian conquests of Alexander the Great in 335 BCE to the founding of Islam in the 7th century CE.[5] The birth and expansion of Islam during the 7th century was quickly followed by its Hellenization. Knowledge of Greek conceptions of the world was preserved and absorbed into Islamic theology, law, culture, and commerce, which were aided by the translations of traditional Greek texts and some Syriac intermediary sources into Arabic during the 8th–9th century.

Education and scholarly pursuits

Madrasas were centers for many different religious and scientific studies and were the culmination of different institutions such as mosques based around religious studies, housing for out-of-town visitors, and finally educational institutions focused on the natural sciences.[123] Unlike Western universities, students at a madrasa would learn from one specific teacher, who would issue a certificate at the completion of their studies called an Ijazah. An Ijazah differs from a western university degree in many ways one being that it is issued by a single person rather than an institution, and another being that it is not an individual degree declaring adequate knowledge over broad subjects, but rather a license to teach and pass on a very specific set of texts.[124] Women were also allowed to attend madrasas, as both students and teachers, something not seen in high western education until the 1800s.[124] Madrasas were more than just academic centers. The Suleymaniye Mosque, for example, was one of the earliest and most well-known madrasas, which was built by Suleiman the Magnificent in the 16th century[125] The Suleymaniye Mosque was home to a hospital and medical college, a kitchen, and children's school, as well as serving as a temporary home for travelers.[125]

Higher education at a madrasa (or college) was focused on Islamic law and religious science and students had to engage in self-study for everything else.[5] And despite the occasional theological backlash, many Islamic scholars of science were able to conduct their work in relatively tolerant urban centers (e.g., Baghdad and Cairo) and were protected by powerful patrons.[5] They could also travel freely and exchange ideas as there were no political barriers within the unified Islamic state.[5] Islamic science during this time was primarily focused on the correction, extension, articulation, and application of Greek ideas to new problems.[5]

Advancements in mathematics

Most of the achievements by Islamic scholars during this period were in mathematics.[5] Arabic mathematics was a direct descendant of Greek and Indian mathematics.[5] For instance, what is now known as Arabic numerals originally came from India, but Muslim mathematicians made several key refinements to the number system, such as the introduction of decimal point notation. Mathematicians such as Muhammad ibn Musa al-Khwarizmi (c. 780–850) gave his name to the concept of the algorithm, while the term algebra is derived from al-jabr, the beginning of the title of one of his publications.[126] Islamic trigonometry continued from the works of Ptolemy's Almagest and Indian Siddhanta, from which they added trigonometric functions, drew up tables, and applied trignometry to spheres and planes. Many of their engineers, instruments makers, and surveyors contributed books in applied mathematics. It was in astronomy where Islamic mathematicians made their greatest contributions. Al-Battani (c. 858–929) improved the measurements of Hipparchus, preserved in the translation of Ptolemy's Hè Megalè Syntaxis (The great treatise) translated as Almagest. Al-Battani also improved the precision of the measurement of the precession of the Earth's axis. Corrections were made to Ptolemy's geocentric model by al-Battani, Ibn al-Haytham,[127] Averroes and the Maragha astronomers such as Nasir al-Din al-Tusi, Mu'ayyad al-Din al-Urdi and Ibn al-Shatir.[128][129]

Scholars with geometric skills made significant improvements to the earlier classical texts on light and sight by Euclid, Aristotle, and Ptolemy.[5] The earliest surviving Arabic treatises were written in the 9th century by Abū Ishāq al-Kindī, Qustā ibn Lūqā, and (in fragmentary form) Ahmad ibn Isā. Later in the 11th century, Ibn al-Haytham (known as Alhazen in the West), a mathematician and astronomer, synthesized a new theory of vision based on the works of his predecessors.[5] His new theory included a complete system of geometrical optics, which was set in great detail in his Book of Optics.[5][130] His book was translated into Latin and was relied upon as a principal source on the science of optics in Europe until the 17th century.[5]

Institutionalization of medicine

The medical sciences were prominently cultivated in the Islamic world.[5] The works of Greek medical theories, especially those of Galen, were translated into Arabic and there was an outpouring of medical texts by Islamic physicians, which were aimed at organizing, elaborating, and disseminating classical medical knowledge.[5] Medical specialties started to emerge, such as those involved in the treatment of eye diseases such as cataracts. Ibn Sina (known as Avicenna in the West, c. 980–1037) was a prolific Persian medical encyclopedist[131] wrote extensively on medicine,[132][133] with his two most notable works in medicine being the Kitāb al-shifāʾ ("Book of Healing") and The Canon of Medicine, both of which were used as standard medicinal texts in both the Muslim world and in Europe well into the 17th century. Amongst his many contributions are the discovery of the contagious nature of infectious diseases,[132] and the introduction of clinical pharmacology.[134] Institutionalization of medicine was another important achievement in the Islamic world. Although hospitals as an institution for the sick emerged in the Byzantium empire, the model of institutionalized medicine for all social classes was extensive in the Islamic empire and was scattered throughout. In addition to treating patients, physicians could teach apprentice physicians, as well write and do research. The discovery of the pulmonary transit of blood in the human body by Ibn al-Nafis occurred in a hospital setting.[5]

Decline

Islamic science began its decline in the 12th–13th century, before the Renaissance in Europe, due in part to the Christian reconquest of Spain and the Mongol conquests in the East in the 11th–13th century. The Mongols sacked Baghdad, capital of the Abbasid caliphate, in 1258, which ended the Abbasid empire.[5][135] Nevertheless, many of the conquerors became patrons of the sciences. Hulagu Khan, for example, who led the siege of Baghdad, became a patron of the Maragheh observatory.[5] Islamic astronomy continued to flourish into the 16th century.[5]

Western Europe

By the eleventh century, most of Europe had become Christian; stronger monarchies emerged; borders were restored; technological developments and agricultural innovations were made, increasing the food supply and population. Classical Greek texts were translated from Arabic and Greek into Latin, stimulating scientific discussion in Western Europe.[136]

In classical antiquity, Greek and Roman taboos had meant that dissection was usually banned, but in the Middle Ages medical teachers and students at Bologna began to open human bodies, and Mondino de Luzzi (c.1275–1326) produced the first known anatomy textbook based on human dissection.[137][138]

As a result of the Pax Mongolica, Europeans, such as Marco Polo, began to venture further and further east. The written accounts of Polo and his fellow travelers inspired other Western European maritime explorers to search for a direct sea route to Asia, ultimately leading to the Age of Discovery.[139]

Technological advances were also made, such as the early flight of Eilmer of Malmesbury (who had studied mathematics in 11th-century England),[140] and the metallurgical achievements of the Cistercian blast furnace at Laskill.[141][142]

Medieval universities

An intellectual revitalization of Western Europe started with the birth of medieval universities in the 12th century. These urban institutions grew from the informal scholarly activities of learned friars who visited monasteries, consulted libraries, and conversed with other fellow scholars.[143] A friar who became well-known would attract a following of disciples, giving rise to a brotherhood of scholars (or collegium in Latin). A collegium might travel to a town or request a monastery to host them. However, if the number of scholars within a collegium grew too large, they would opt to settle in a town instead.[143] As the number of collegia within a town grew, the collegia might request that their king grant them a charter that would convert them into a universitas.[143] Many universities were chartered during this period, with the first in Bologna in 1088, followed by Paris in 1150, Oxford in 1167, and Cambridge in 1231.[143] The granting of a charter meant that the medieval universities were partially sovereign and independent from local authorities.[143] Their independence allowed them to conduct themselves and judge their own members based on their own rules. Furthermore, as initially religious institutions, their faculties and students were protected from capital punishment (e.g., gallows).[143] Such independence was a matter of custom, which could, in principle, be revoked by their respective rulers if they felt threatened. Discussions of various subjects or claims at these medieval institutions, no matter how controversial, were done in a formalized way so as to declare such discussions as being within the bounds of a university and therefore protected by the privileges of that institution's sovereignty.[143] A claim could be described as ex cathedra (literally "from the chair", used within the context of teaching) or ex hypothesi (by hypothesis). This meant that the discussions were presented as purely an intellectual exercise that did not require those involved to commit themselves to the truth of a claim or to proselytize. Modern academic concepts and practices such as academic freedom or freedom of inquiry are remnants of these medieval privileges that were tolerated in the past.[143]

The curriculum of these medieval institutions centered on the seven liberal arts, which were aimed at providing beginning students with the skills for reasoning and scholarly language.[143] Students would begin their studies starting with the first three liberal arts or Trivium (grammar, rhetoric, and logic) followed by the next four liberal arts or Quadrivium (arithmetic, geometry, astronomy, and music).[143][113] Those who completed these requirements and received their baccalaureate (or Bachelor of Arts) had the option to join the higher faculty (law, medicine, or theology), which would confer an LLD for a lawyer, an MD for a physician, or ThD for a theologian.[143] Students who chose to remain in the lower faculty (arts) could work towards a Magister (or Master's) degree and would study three philosophies: metaphysics, ethics, and natural philosophy.[143] Latin translations of Aristotle's works such as De Anima (On the Soul) and the commentaries on them were required readings. As time passed, the lower faculty was allowed to confer its own doctoral degree called the PhD.[143] Many of the Masters were drawn to encyclopedias and had used them as textbooks. But these scholars yearned for the complete original texts of the Ancient Greek philosophers, mathematicians, and physicians such as Aristotle, Euclid, and Galen, which were not available to them at the time. These Ancient Greek texts were to be found in the Byzantine Empire and the Islamic World.[143]

Translations of Greek and Arabic sources

Contact with the Byzantine Empire,[120] and with the Islamic world during the Reconquista and the Crusades, allowed Latin Europe access to scientific Greek and Arabic texts, including the works of Aristotle, Ptolemy, Isidore of Miletus, John Philoponus, Jābir ibn Hayyān, al-Khwarizmi, Alhazen, Avicenna, and Averroes. European scholars had access to the translation programs of Raymond of Toledo, who sponsored the 12th century Toledo School of Translators from Arabic to Latin. Later translators like Michael Scotus would learn Arabic in order to study these texts directly. The European universities aided materially in the translation and propagation of these texts and started a new infrastructure which was needed for scientific communities. In fact, European university put many works about the natural world and the study of nature at the center of its curriculum,[144] with the result that the "medieval university laid far greater emphasis on science than does its modern counterpart and descendent."[145]

At the beginning of the 13th century, there were reasonably accurate Latin translations of the main works of almost all the intellectually crucial ancient authors, allowing a sound transfer of scientific ideas via both the universities and the monasteries. By then, the natural philosophy in these texts began to be extended by scholastics such as Robert Grosseteste, Roger Bacon, Albertus Magnus and Duns Scotus. Precursors of the modern scientific method, influenced by earlier contributions of the Islamic world, can be seen already in Grosseteste's emphasis on mathematics as a way to understand nature, and in the empirical approach admired by Bacon, particularly in his Opus Majus. Pierre Duhem's thesis is that Stephen Tempier – the Bishop of Paris – Condemnation of 1277 led to the study of medieval science as a serious discipline, "but no one in the field any longer endorses his view that modern science started in 1277".[146] However, many scholars agree with Duhem's view that the mid-late Middle Ages saw important scientific developments.[147][148][149]

Medieval science

The first half of the 14th century saw much important scientific work, largely within the framework of scholastic commentaries on Aristotle's scientific writings.[150] William of Ockham emphasized the principle of parsimony: natural philosophers should not postulate unnecessary entities, so that motion is not a distinct thing but is only the moving object[151] and an intermediary "sensible species" is not needed to transmit an image of an object to the eye.[152] Scholars such as Jean Buridan and Nicole Oresme started to reinterpret elements of Aristotle's mechanics. In particular, Buridan developed the theory that impetus was the cause of the motion of projectiles, which was a first step towards the modern concept of inertia.[153] The Oxford Calculators began to mathematically analyze the kinematics of motion, making this analysis without considering the causes of motion.[154]

In 1348, the Black Death and other disasters sealed a sudden end to philosophic and scientific development. Yet, the rediscovery of ancient texts was stimulated by the Fall of Constantinople in 1453, when many Byzantine scholars sought refuge in the West. Meanwhile, the introduction of printing was to have great effect on European society. The facilitated dissemination of the printed word democratized learning and allowed ideas such as algebra to propagate more rapidly. These developments paved the way for the Scientific Revolution, where scientific inquiry, halted at the start of the Black Death, resumed.[155][156]

Renaissance

Revival of learning

The renewal of learning in Europe began with 12th century Scholasticism. The Northern Renaissance showed a decisive shift in focus from Aristotelian natural philosophy to chemistry and the biological sciences (botany, anatomy, and medicine).[157] Thus modern science in Europe was resumed in a period of great upheaval: the Protestant Reformation and Catholic Counter-Reformation; the discovery of the Americas by Christopher Columbus; the Fall of Constantinople; but also the re-discovery of Aristotle during the Scholastic period presaged large social and political changes. Thus, a suitable environment was created in which it became possible to question scientific doctrine, in much the same way that Martin Luther and John Calvin questioned religious doctrine. The works of Ptolemy (astronomy) and Galen (medicine) were found not always to match everyday observations. Work by Vesalius on human cadavers found problems with the Galenic view of anatomy.[158]

Theophrastus' work on rocks, Peri lithōn, remained authoritative for millennia: its interpretation of fossils was not overturned until after the Scientific Revolution.

During the Italian Renaissance, Niccolò Machiavelli established the emphasis of modern political science on direct empirical observation of political institutions and actors. Later, the expansion of the scientific paradigm during the Enlightenment further pushed the study of politics beyond normative determinations. In particular, the study of statistics, to study the subjects of the state, has been applied to polling and voting.

In archaeology, the 15th and 16th centuries saw the rise of antiquarians in Renaissance Europe who were interested in the collection of artifacts.

Scientific Revolution and birth of New Science

Galileo Galilei, father of modern science.

The early modern period is seen as a flowering of the European Renaissance. There was a willingness to question previously held truths and search for new answers resulted in a period of major scientific advancements, now known as the Scientific Revolution, which led to the emergence of a New Science that was more mechanistic in its worldview, more integrated with mathematics, and more reliable and open as its knowledge was based on a newly defined scientific method.[11][14][15][159] The Scientific Revolution is a convenient boundary between ancient thought and classical physics, and is traditionally held by most historians to have begun in 1543, when the books De humani corporis fabrica (On the Workings of the Human Body) by Andreas Vesalius, and also De Revolutionibus, by the astronomer Nicolaus Copernicus, were first printed. The period culminated with the publication of the Philosophiæ Naturalis Principia Mathematica in 1687 by Isaac Newton, representative of the unprecedented growth of scientific publications throughout Europe.

Other significant scientific advances were made during this time by Galileo Galilei, Johannes Kepler, Edmond Halley, William Harvey, Pierre Fermat, Robert Hooke, Christiaan Huygens, Tycho Brahe, Marin Mersenne, Gottfried Leibniz, Isaac Newton, and Blaise Pascal.[160] In philosophy, major contributions were made by Francis Bacon, Sir Thomas Browne, René Descartes, Baruch Spinoza, Pierre Gassendi, Robert Boyle, and Thomas Hobbes.[160] Christiaan Huygens derived the centripetal and centrifugal forces and was the first to transfer mathematical inquiry to describe unobservable physical phenomena. William Gilbert did some of the earliest experiments with electricity and magnetism, establishing that the Earth itself is magnetic.

Heliocentrism

The heliocentric astronomical model of the universe was refined by Nicolaus Copernicus. Copernicus proposed the idea that the Earth and all heavenly spheres, containing the planets and other objects in the cosmos, rotated around the Sun.[161] His heliocentric model also proposed that all stars were fixed and did not rotate on an axis, nor in any motion at all.[162] His theory proposed the yearly rotation of the Earth and the other heavenly spheres around the Sun and was able to calculate the distances of planets using deferents and epicycles. Although these calculations were not completely accurate, Copernicus was able to understand the distance order of each heavenly sphere. The Copernican heliocentric system was a revival of the hypotheses of Aristarchus of Samos and Seleucus of Seleucia.[163] Aristarchus of Samos did propose that the Earth rotated around the Sun but did not mention anything about the other heavenly spheres' order, motion, or rotation.[164] Seleucus of Seleucia also proposed the rotation of the Earth around the Sun but did not mention anything about the other heavenly spheres. In addition, Seleucus of Seleucia understood that the Moon rotated around the Earth and could be used to explain the tides of the oceans, thus further proving his understanding of the heliocentric idea.[165]

Newly defined scientific method

The scientific method was also better developed as the modern way of thinking emphasized experimentation and reason over traditional considerations. Galileo ("Father of Modern Physics") also made use of experiments to validate physical theories, a key element of the scientific method.

Age of Enlightenment

Continuation of Scientific Revolution

The Scientific Revolution continued into the Age of Enlightenment, which accelerated the development of modern science.

Planets and orbits

The heliocentric model revived by Nicolaus Copernicus was followed by the model of planetary motion given by Johannes Kepler in the early 17th century, which proposed that the planets follow elliptical orbits, with the Sun at one focus of the ellipse.

Calculus and Newtonian mechanics

In 1687, Isaac Newton published the Principia Mathematica, detailing two comprehensive and successful physical theories: Newton's laws of motion, which led to classical mechanics; and Newton's law of universal gravitation, which describes the fundamental force of gravity.

Emergence of chemistry

A decisive moment came when "chemistry" was distinguished from alchemy by Robert Boyle in his work The Sceptical Chymist, in 1661; although the alchemical tradition continued for some time after his work. Other important steps included the gravimetric experimental practices of medical chemists like William Cullen, Joseph Black, Torbern Bergman and Pierre Macquer and through the work of Antoine Lavoisier ("father of modern chemistry") on oxygen and the law of conservation of mass, which refuted phlogiston theory. Modern chemistry emerged from the sixteenth through the eighteenth centuries through the material practices and theories promoted by alchemy, medicine, manufacturing and mining.[166][167][168]

Circulatory system

William Harvey published De Motu Cordis in 1628, which revealed his conclusions based on his extensive studies of vertebrate circulatory systems.[160] He identified the central role of the heart, arteries, and veins in producing blood movement in a circuit, and failed to find any confirmation of Galen's pre-existing notions of heating and cooling functions.[169] The history of early modern biology and medicine is often told through the search for the seat of the soul.[170] Galen in his descriptions of his foundational work in medicine presents the distinctions between arteries, veins, and nerves using the vocabulary of the soul.[171]

Scientific societies and journals

A critical innovation was the creation of permanent scientific societies and their scholarly journals, which dramatically sped the diffusion of new ideas. Typical was the founding of the Royal Society in London in 1660 and its journal in 1665 the Philosophical Transaction of the Royal Society, the first scientific journal in English.[172] 1665 also saw the first journal in French, the Journal des sçavans. Science drawing on the works[173] of Newton, Descartes, Pascal and Leibniz, science was on a path to modern mathematics, physics and technology by the time of the generation of Benjamin Franklin (1706–1790), Leonhard Euler (1707–1783), Mikhail Lomonosov (1711–1765) and Jean le Rond d'Alembert (1717–1783). Denis Diderot's Encyclopédie, published between 1751 and 1772 brought this new understanding to a wider audience. The impact of this process was not limited to science and technology, but affected philosophy (Immanuel Kant, David Hume), religion (the increasingly significant impact of science upon religion), and society and politics in general (Adam Smith, Voltaire).

Developments in geology

Geology did not undergo systematic restructuring during the Scientific Revolution but instead existed as a cloud of isolated, disconnected ideas about rocks, minerals, and landforms long before it became a coherent science. Robert Hooke formulated a theory of earthquakes, and Nicholas Steno developed the theory of superposition and argued that fossils were the remains of once-living creatures. Beginning with Thomas Burnet's Sacred Theory of the Earth in 1681, natural philosophers began to explore the idea that the Earth had changed over time. Burnet and his contemporaries interpreted Earth's past in terms of events described in the Bible, but their work laid the intellectual foundations for secular interpretations of Earth history.

Bioelectricity

During the late 18th century, researchers such as Hugh Williamson[174] and John Walsh experimented on the effects of electricity on the human body. Further studies by Luigi Galvani and Alessandro Volta established the electrical nature of what Volta called galvanism.[175][176]

Developments in geology

1812 skeletal and muscular reconstruction of Anoplotherium commune by Georges Cuvier based on fossil remains from the Paris Basin

Modern geology, like modern chemistry, gradually evolved during the 18th and early 19th centuries. Benoît de Maillet and the Comte de Buffon saw the Earth as much older than the 6,000 years envisioned by biblical scholars. Jean-Étienne Guettard and Nicolas Desmarest hiked central France and recorded their observations on some of the first geological maps. Aided by chemical experimentation, naturalists such as Scotland's John Walker,[177] Sweden's Torbern Bergman, and Germany's Abraham Werner created comprehensive classification systems for rocks and minerals—a collective achievement that transformed geology into a cutting edge field by the end of the eighteenth century. These early geologists also proposed a generalized interpretations of Earth history that led James Hutton, Georges Cuvier and Alexandre Brongniart, following in the steps of Steno, to argue that layers of rock could be dated by the fossils they contained: a principle first applied to the geology of the Paris Basin. The use of index fossils became a powerful tool for making geological maps, because it allowed geologists to correlate the rocks in one locality with those of similar age in other, distant localities.

Birth of modern economics

Adam Smith wrote The Wealth of Nations, the first modern work of economics

The basis for classical economics forms Adam Smith's An Inquiry into the Nature and Causes of the Wealth of Nations, published in 1776. Smith criticized mercantilism, advocating a system of free trade with division of labour. He postulated an "invisible hand" that regulated economic systems made up of actors guided only by self-interest. The "invisible hand" mentioned in a lost page in the middle of a chapter in the middle of the "Wealth of Nations", 1776, advances as Smith's central message.

Social science

Anthropology can best be understood as an outgrowth of the Age of Enlightenment. It was during this period that Europeans attempted systematically to study human behavior. Traditions of jurisprudence, history, philology and sociology developed during this time and informed the development of the social sciences of which anthropology was a part.

19th century

The 19th century saw the birth of science as a profession. William Whewell had coined the term scientist in 1833,[178] which soon replaced the older term natural philosopher.

Developments in physics

Alessandro Volta demonstrates the first electrical cell to Napoleon in 1801.

In physics, the behavior of electricity and magnetism was studied by Giovanni Aldini, Alessandro Volta, Michael Faraday, Georg Ohm, and others. The experiments, theories and discoveries of Michael Faraday, Andre-Marie Ampere, James Clerk Maxwell, and their contemporaries led to the unification of the two phenomena into a single theory of electromagnetism as described by Maxwell's equations. Thermodynamics led to an understanding of heat and the notion of energy being defined.

Discovery of Neptune

In astronomy, the planet Neptune was discovered. Advances in astronomy and in optical systems in the 19th century resulted in the first observation of an asteroid (1 Ceres) in 1801, and the discovery of Neptune in 1846.

Developments in mathematics

In mathematics, the notion of complex numbers finally matured and led to a subsequent analytical theory; they also began the use of hypercomplex numbers. Karl Weierstrass and others carried out the arithmetization of analysis for functions of real and complex variables. It also saw rise to new progress in geometry beyond those classical theories of Euclid, after a period of nearly two thousand years. The mathematical science of logic likewise had revolutionary breakthroughs after a similarly long period of stagnation. But the most important step in science at this time were the ideas formulated by the creators of electrical science. Their work changed the face of physics and made possible for new technology to come about such as electric power, electrical telegraphy, the telephone, and radio.

Developments in chemistry

In chemistry, Dmitri Mendeleev, following the atomic theory of John Dalton, created the first periodic table of elements. Other highlights include the discoveries unveiling the nature of atomic structure and matter, simultaneously with chemistry – and of new kinds of radiation. The theory that all matter is made of atoms, which are the smallest constituents of matter that cannot be broken down without losing the basic chemical and physical properties of that matter, was provided by John Dalton in 1803, although the question took a hundred years to settle as proven. Dalton also formulated the law of mass relationships. In 1869, Dmitri Mendeleev composed his periodic table of elements on the basis of Dalton's discoveries. The synthesis of urea by Friedrich Wöhler opened a new research field, organic chemistry, and by the end of the 19th century, scientists were able to synthesize hundreds of organic compounds. The later part of the 19th century saw the exploitation of the Earth's petrochemicals, after the exhaustion of the oil supply from whaling. By the 20th century, systematic production of refined materials provided a ready supply of products which provided not only energy, but also synthetic materials for clothing, medicine, and everyday disposable resources. Application of the techniques of organic chemistry to living organisms resulted in physiological chemistry, the precursor to biochemistry.

Age of the Earth

Over the first half of the 19th century, geologists such as Charles Lyell, Adam Sedgwick, and Roderick Murchison applied the new technique to rocks throughout Europe and eastern North America, setting the stage for more detailed, government-funded mapping projects in later decades. Midway through the 19th century, the focus of geology shifted from description and classification to attempts to understand how the surface of the Earth had changed. The first comprehensive theories of mountain building were proposed during this period, as were the first modern theories of earthquakes and volcanoes. Louis Agassiz and others established the reality of continent-covering ice ages, and "fluvialists" like Andrew Crombie Ramsay argued that river valleys were formed, over millions of years by the rivers that flow through them. After the discovery of radioactivity, radiometric dating methods were developed, starting in the 20th century. Alfred Wegener's theory of "continental drift" was widely dismissed when he proposed it in the 1910s, but new data gathered in the 1950s and 1960s led to the theory of plate tectonics, which provided a plausible mechanism for it. Plate tectonics also provided a unified explanation for a wide range of seemingly unrelated geological phenomena. Since 1970 it has served as the unifying principle in geology.

Evolution and inheritance

In mid-July 1837 Charles Darwin started his "B" notebook on the Transmutation of Species, and on page 36 wrote "I think" above his first evolutionary tree.

Perhaps the most prominent, controversial, and far-reaching theory in all of science has been the theory of evolution by natural selection, which was independently formulated by Charles Darwin and Alfred Wallace. It was described in detail in Darwin's book The Origin of Species, which was published in 1859. In it, Darwin proposed that the features of all living things, including humans, were shaped by natural processes over long periods of time. The theory of evolution in its current form affects almost all areas of biology.[179] Implications of evolution on fields outside of pure science have led to both opposition and support from different parts of society, and profoundly influenced the popular understanding of "man's place in the universe". Separately, Gregor Mendel formulated in the principles of inheritance in 1866, which became the basis of modern genetics.

Germ theory

Another important landmark in medicine and biology were the successful efforts to prove the germ theory of disease. Following this, Louis Pasteur made the first vaccine against rabies, and also made many discoveries in the field of chemistry, including the asymmetry of crystals. In 1847, Hungarian physician Ignác Fülöp Semmelweis dramatically reduced the occurrence of puerperal fever by simply requiring physicians to wash their hands before attending to women in childbirth. This discovery predated the germ theory of disease. However, Semmelweis' findings were not appreciated by his contemporaries and handwashing came into use only with discoveries by British surgeon Joseph Lister, who in 1865 proved the principles of antisepsis. Lister's work was based on the important findings by French biologist Louis Pasteur. Pasteur was able to link microorganisms with disease, revolutionizing medicine. He also devised one of the most important methods in preventive medicine, when in 1880 he produced a vaccine against rabies. Pasteur invented the process of pasteurization, to help prevent the spread of disease through milk and other foods.[180]

Schools of economics

Karl Marx developed an alternative economic theory, called Marxian economics. Marxian economics is based on the labor theory of value and assumes the value of good to be based on the amount of labor required to produce it. Under this axiom, capitalism was based on employers not paying the full value of workers labor to create profit. The Austrian School responded to Marxian economics by viewing entrepreneurship as driving force of economic development. This replaced the labor theory of value by a system of supply and demand.

Founding of psychology

Psychology as a scientific enterprise that was independent from philosophy began in 1879 when Wilhelm Wundt founded the first laboratory dedicated exclusively to psychological research (in Leipzig). Other important early contributors to the field include Hermann Ebbinghaus (a pioneer in memory studies), Ivan Pavlov (who discovered classical conditioning), William James, and Sigmund Freud. Freud's influence has been enormous, though more as cultural icon than a force in scientific psychology.

Modern sociology

Modern sociology emerged in the early 19th century as the academic response to the modernization of the world. Among many early sociologists (e.g., Émile Durkheim), the aim of sociology was in structuralism, understanding the cohesion of social groups, and developing an "antidote" to social disintegration. Max Weber was concerned with the modernization of society through the concept of rationalization, which he believed would trap individuals in an "iron cage" of rational thought. Some sociologists, including Georg Simmel and W. E. B. Du Bois, used more microsociological, qualitative analyses. This microlevel approach played an important role in American sociology, with the theories of George Herbert Mead and his student Herbert Blumer resulting in the creation of the symbolic interactionism approach to sociology. In particular, just Auguste Comte, illustrated with his work the transition from a theological to a metaphysical stage and, from this, to a positive stage. Comte took care of the classification of the sciences as well as a transit of humanity towards a situation of progress attributable to a re-examination of nature according to the affirmation of 'sociality' as the basis of the scientifically interpreted society.[181]

Romanticism

The Romantic Movement of the early 19th century reshaped science by opening up new pursuits unexpected in the classical approaches of the Enlightenment. The decline of Romanticism occurred because a new movement, Positivism, began to take hold of the ideals of the intellectuals after 1840 and lasted until about 1880. At the same time, the romantic reaction to the Enlightenment produced thinkers such as Johann Gottfried Herder and later Wilhelm Dilthey whose work formed the basis for the culture concept which is central to the discipline. Traditionally, much of the history of the subject was based on colonial encounters between Western Europe and the rest of the world, and much of 18th- and 19th-century anthropology is now classed as scientific racism. During the late 19th century, battles over the "study of man" took place between those of an "anthropological" persuasion (relying on anthropometrical techniques) and those of an "ethnological" persuasion (looking at cultures and traditions), and these distinctions became part of the later divide between physical anthropology and cultural anthropology, the latter ushered in by the students of Franz Boas.

20th century

Science advanced dramatically during the 20th century. There were new and radical developments in the physical and life sciences, building on the progress from the 19th century.[182]

Theory of relativity and quantum mechanics

Einstein's official portrait after receiving the 1921 Nobel Prize in Physics

The beginning of the 20th century brought the start of a revolution in physics. The long-held theories of Newton were shown not to be correct in all circumstances. Beginning in 1900, Max Planck, Albert Einstein, Niels Bohr and others developed quantum theories to explain various anomalous experimental results, by introducing discrete energy levels. Not only did quantum mechanics show that the laws of motion did not hold on small scales, but the theory of general relativity, proposed by Einstein in 1915, showed that the fixed background of spacetime, on which both Newtonian mechanics and special relativity depended, could not exist. In 1925, Werner Heisenberg and Erwin Schrödinger formulated quantum mechanics, which explained the preceding quantum theories. Currently, general relativity and quantum mechanics are inconsistent with each other, and efforts are underway to unify the two.

Big Bang

The observation by Edwin Hubble in 1929 that the speed at which galaxies recede positively correlates with their distance, led to the understanding that the universe is expanding, and the formulation of the Big Bang theory by Georges Lemaître. George Gamow, Ralph Alpher, and Robert Herman had calculated that there should be evidence for a Big Bang in the background temperature of the universe.[183] In 1964, Arno Penzias and Robert Wilson[184] discovered a 3 Kelvin background hiss in their Bell Labs radiotelescope (the Holmdel Horn Antenna), which was evidence for this hypothesis, and formed the basis for a number of results that helped determine the age of the universe.

Big science

The atomic bomb ushered in "Big Science" in physics.

In 1938 Otto Hahn and Fritz Strassmann discovered nuclear fission with radiochemical methods, and in 1939 Lise Meitner and Otto Robert Frisch wrote the first theoretical interpretation of the fission process, which was later improved by Niels Bohr and John A. Wheeler. Further developments took place during World War II, which led to the practical application of radar and the development and use of the atomic bomb. Around this time, Chien-Shiung Wu was recruited by the Manhattan Project to help develop a process for separating uranium metal into U-235 and U-238 isotopes by Gaseous diffusion.[185] She was an expert experimentalist in beta decay and weak interaction physics.[186][187] Wu designed an experiment (see Wu experiment) that enabled theoretical physicists Tsung-Dao Lee and Chen-Ning Yang to disprove the law of parity experimentally, winning them a Nobel Prize in 1957.[186]

Though the process had begun with the invention of the cyclotron by Ernest O. Lawrence in the 1930s, physics in the postwar period entered into a phase of what historians have called "Big Science", requiring massive machines, budgets, and laboratories in order to test their theories and move into new frontiers. The primary patron of physics became state governments, who recognized that the support of "basic" research could often lead to technologies useful to both military and industrial applications.

Advances in genetics

Watson and Crick used many aluminium templates like this one, which is the single base Adenine (A), to build a physical model of DNA in 1953.

In the early 20th century, the study of heredity became a major investigation after the rediscovery in 1900 of the laws of inheritance developed by Mendel.[188] The 20th century also saw the integration of physics and chemistry, with chemical properties explained as the result of the electronic structure of the atom. Linus Pauling's book on The Nature of the Chemical Bond used the principles of quantum mechanics to deduce bond angles in ever-more complicated molecules. Pauling's work culminated in the physical modelling of DNA, the secret of life (in the words of Francis Crick, 1953). In the same year, the Miller–Urey experiment demonstrated in a simulation of primordial processes, that basic constituents of proteins, simple amino acids, could themselves be built up from simpler molecules, kickstarting decades of research into the chemical origins of life. By 1953, James D. Watson and Francis Crick clarified the basic structure of DNA, the genetic material for expressing life in all its forms,[189] building on the work of Maurice Wilkins and Rosalind Franklin, suggested that the structure of DNA was a double helix. In their famous paper "Molecular structure of Nucleic Acids"[189] In the late 20th century, the possibilities of genetic engineering became practical for the first time, and a massive international effort began in 1990 to map out an entire human genome (the Human Genome Project). The discipline of ecology typically traces its origin to the synthesis of Darwinian evolution and Humboldtian biogeography, in the late 19th and early 20th centuries. Equally important in the rise of ecology, however, were microbiology and soil science—particularly the cycle of life concept, prominent in the work Louis Pasteur and Ferdinand Cohn. The word ecology was coined by Ernst Haeckel, whose particularly holistic view of nature in general (and Darwin's theory in particular) was important in the spread of ecological thinking. In the 1930s, Arthur Tansley and others began developing the field of ecosystem ecology, which combined experimental soil science with physiological concepts of energy and the techniques of field biology.

Space exploration

In 1925, Cecilia Payne-Gaposchkin determined that stars were composed mostly of hydrogen and helium.[190] She was dissuaded by astronomer Henry Norris Russell from publishing this finding in her PhD thesis because of the widely held belief that stars had the same composition as the Earth.[191] However, four years later, in 1929, Henry Norris Russell came to the same conclusion through different reasoning and the discovery was eventually accepted.[191]

In 1987, supernova SN 1987A was observed by astronomers on Earth both visually, and in a triumph for neutrino astronomy, by the solar neutrino detectors at Kamiokande. But the solar neutrino flux was a fraction of its theoretically expected value. This discrepancy forced a change in some values in the standard model for particle physics.

Neuroscience as a distinct discipline

The understanding of neurons and the nervous system became increasingly precise and molecular during the 20th century. For example, in 1952, Alan Lloyd Hodgkin and Andrew Huxley presented a mathematical model for transmission of electrical signals in neurons of the giant axon of a squid, which they called "action potentials", and how they are initiated and propagated, known as the Hodgkin–Huxley model. In 1961–1962, Richard FitzHugh and J. Nagumo simplified Hodgkin–Huxley, in what is called the FitzHugh–Nagumo model. In 1962, Bernard Katz modeled neurotransmission across the space between neurons known as synapses. Beginning in 1966, Eric Kandel and collaborators examined biochemical changes in neurons associated with learning and memory storage in Aplysia. In 1981 Catherine Morris and Harold Lecar combined these models in the Morris–Lecar model. Such increasingly quantitative work gave rise to numerous biological neuron models and models of neural computation. Neuroscience began to be recognized as a distinct academic discipline in its own right. Eric Kandel and collaborators have cited David Rioch, Francis O. Schmitt, and Stephen Kuffler as having played critical roles in establishing the field.[192]

Plate tectonics

Alfred Wegener in Greenland in the winter of 1912–13. He is most remembered as the originator of continental drift hypothesis by suggesting in 1912 that the continents are slowly drifting around the Earth.

Geologists' embrace of plate tectonics became part of a broadening of the field from a study of rocks into a study of the Earth as a planet. Other elements of this transformation include: geophysical studies of the interior of the Earth, the grouping of geology with meteorology and oceanography as one of the "earth sciences", and comparisons of Earth and the solar system's other rocky planets.

Applications

In terms of applications, a massive number of new technologies were developed in the 20th century. Technologies such as electricity, the incandescent light bulb, the automobile and the phonograph, first developed at the end of the 19th century, were perfected and universally deployed. The first car was introduced by Karl Benz in 1885.[193] The first airplane flight occurred in 1903, and by the end of the century airliners flew thousands of miles in a matter of hours. The development of the radio, television and computers caused massive changes in the dissemination of information. Advances in biology also led to large increases in food production, as well as the elimination of diseases such as polio by Dr. Jonas Salk. Gene mapping and gene sequencing, invented by Drs. Mark Skolnik and Walter Gilbert, respectively, are the two technologies that made the Human Genome Project feasible. Computer science, built upon a foundation of theoretical linguistics, discrete mathematics, and electrical engineering, studies the nature and limits of computation. Subfields include computability, computational complexity, database design, computer networking, artificial intelligence, and the design of computer hardware. One area in which advances in computing have contributed to more general scientific development is by facilitating large-scale archiving of scientific data. Contemporary computer science typically distinguishes itself by emphasizing mathematical 'theory' in contrast to the practical emphasis of software engineering.

Einstein's paper "On the Quantum Theory of Radiation" outlined the principles of the stimulated emission of photons. This led to the invention of the Laser (light amplification by the stimulated emission of radiation) and the optical amplifier which ushered in the Information Age.[194] It is optical amplification that allows fiber optic networks to transmit the massive capacity of the Internet.

Based on wireless transmission of electromagnetic radiation and global networks of cellular operation, the mobile phone became a primary means to access the internet.[195]

Developments in political science and economics

In political science during the 20th century, the study of ideology, behaviouralism and international relations led to a multitude of 'pol-sci' subdisciplines including rational choice theory, voting theory, game theory (also used in economics), psephology, political geography/geopolitics, political anthropology/political psychology/political sociology, political economy, policy analysis, public administration, comparative political analysis and peace studies/conflict analysis. In economics, John Maynard Keynes prompted a division between microeconomics and macroeconomics in the 1920s. Under Keynesian economics macroeconomic trends can overwhelm economic choices made by individuals. Governments should promote aggregate demand for goods as a means to encourage economic expansion. Following World War II, Milton Friedman created the concept of monetarism. Monetarism focuses on using the supply and demand of money as a method for controlling economic activity. In the 1970s, monetarism has adapted into supply-side economics which advocates reducing taxes as a means to increase the amount of money available for economic expansion. Other modern schools of economic thought are New Classical economics and New Keynesian economics. New Classical economics was developed in the 1970s, emphasizing solid microeconomics as the basis for macroeconomic growth. New Keynesian economics was created partially in response to New Classical economics, and deals with how inefficiencies in the market create a need for control by a central bank or government.

Developments in psychology, sociology, and anthropology

Psychology in the 20th century saw a rejection of Freud's theories as being too unscientific, and a reaction against Edward Titchener's atomistic approach of the mind. This led to the formulation of behaviorism by John B. Watson, which was popularized by B.F. Skinner. Behaviorism proposed epistemologically limiting psychological study to overt behavior, since that could be reliably measured. Scientific knowledge of the "mind" was considered too metaphysical, hence impossible to achieve. The final decades of the 20th century have seen the rise of cognitive science, which considers the mind as once again a subject for investigation, using the tools of psychology, linguistics, computer science, philosophy, and neurobiology. New methods of visualizing the activity of the brain, such as PET scans and CAT scans, began to exert their influence as well, leading some researchers to investigate the mind by investigating the brain, rather than cognition. These new forms of investigation assume that a wide understanding of the human mind is possible, and that such an understanding may be applied to other research domains, such as artificial intelligence. Evolutionary theory was applied to behavior and introduced to anthropology and psychology through the works of cultural anthropologist Napoleon Chagnon; physical anthropology would eventually become evolutionary anthropology, incorporating elements of evolutionary biology with cultural anthropology.

American sociology in the 1940s and 1950s was dominated largely by Talcott Parsons, who argued that aspects of society that promoted structural integration were therefore "functional". This structural functionalism approach was questioned in the 1960s, when sociologists came to see this approach as merely a justification for inequalities present in the status quo. In reaction, conflict theory was developed, which was based in part on the philosophies of Karl Marx. Conflict theorists saw society as an arena in which different groups compete for control over resources. Symbolic interactionism also came to be regarded as central to sociological thinking. Erving Goffman saw social interactions as a stage performance, with individuals preparing "backstage" and attempting to control their audience through impression management. While these theories are currently prominent in sociological thought, other approaches exist, including feminist theory, post-structuralism, rational choice theory, and postmodernism.

In the mid-20th century, much of the methodologies of earlier anthropological and ethnographical study were reevaluated with an eye towards research ethics, while at the same time the scope of investigation has broadened far beyond the traditional study of "primitive cultures".

21st century

One possible signature of a Higgs boson from a simulated proton–proton collision. It decays almost immediately into two jets of hadrons and two electrons, visible as lines.

Higgs boson

On July 4, 2012, physicists working at CERN's Large Hadron Collider announced that they had discovered a new subatomic particle greatly resembling the Higgs boson, a potential key to an understanding of why elementary particles have mass and indeed to the existence of diversity and life in the universe.[196] For now, some physicists are calling it a "Higgslike" particle.[196] Peter Higgs was one of six physicists, working in three independent groups, who, in 1964, invented the notion of the Higgs field ("cosmic molasses"), along with Tom Kibble, Carl Hagen, Gerald Guralnik, François Englert and Robert Brout.[196]

See also

References

  1. Cohen, Eliel (2021). "The boundary lens: theorising academic activity". The University and its Boundaries (1st ed.). New York, New York: Routledge. pp. 14–41. ISBN 978-0367562984. Archived from the original on 5 May 2021. Retrieved 8 June 2021.
  2. Lindberg, David C. (2007). "Science before the Greeks". The Beginnings of Western Science (2nd ed.). Chicago: University of Chicago Press. pp. 1–20. ISBN 978-0-226-48205-7.
  3. Grant, Edward (2007). "Ancient Egypt to Plato". A History of Natural Philosophy. New York: Cambridge University Press. pp. 1–26. ISBN 978-052-1-68957-1.
  4. Lindberg, David C. (2007). "The revival of learning in the West". The Beginnings of Western Science (2nd ed.). Chicago: University of Chicago Press. pp. 193–224. ISBN 978-0-226-48205-7.
  5. Lindberg, David C. (2007). "Islamic science". The Beginnings of Western Science (Second ed.). Chicago: University of Chicago Press. pp. 163–92. ISBN 978-0-226-48205-7.
  6. Lindberg, David C. (2007). "The recovery and assimilation of Greek and Islamic science". The Beginnings of Western Science (2nd ed.). Chicago: University of Chicago Press. pp. 225–253. ISBN 978-0-226-48205-7.
  7. Küskü, Elif Aslan (1 January 2022). "Examination of Scientific Revolution Medicine on the Human Body / Bilimsel Devrim Tıbbını İnsan Bedeni Üzerinden İncelemek". The Legends: Journal of European History Studies. Archived from the original on 12 January 2023. Retrieved 28 September 2022.
  8. Hendrix, Scott E. (2011). "Natural Philosophy or Science in Premodern Epistemic Regimes? The Case of the Astrology of Albert the Great and Galileo Galilei". Teorie Vědy / Theory of Science. 33 (1): 111–132. doi:10.46938/tv.2011.72. S2CID 258069710. Archived from the original on 18 November 2012. Retrieved 20 February 2012.
  9. Principe, Lawrence M. (2011). "Introduction". Scientific Revolution: A Very Short Introduction. New York: Oxford University Press. pp. 1–3. ISBN 978-0-199-56741-6.
  10. Lindberg, David C. (1990). "Conceptions of the Scientific Revolution from Baker to Butterfield: A preliminary sketch". In Lindberg, David C.; Westman, Robert S. (eds.). Reappraisals of the Scientific Revolution (First ed.). Chicago: Cambridge University Press. pp. 1–26. ISBN 978-0-521-34262-9.
  11. Lindberg, David C. (2007). "The legacy of ancient and medieval science". The Beginnings of Western Science (2nd ed.). Chicago: University of Chicago Press. pp. 357–368. ISBN 978-0-226-48205-7.
  12. Del Soldato, Eva (2016). Zalta, Edward N. (ed.). The Stanford Encyclopedia of Philosophy (Fall 2016 ed.). Metaphysics Research Lab, Stanford University. Archived from the original on 11 December 2019. Retrieved 1 June 2018.
  13. Grant, Edward (2007). "Transformation of medieval natural philosophy from the early period modern period to the end of the nineteenth century". A History of Natural Philosophy. New York: Cambridge University Press. pp. 274–322. ISBN 978-052-1-68957-1.
  14. Gal, Ofer (2021). "The New Science". The Origins of Modern Science. New York, New York: Cambridge University Press. pp. 308–349. ISBN 978-1316649701.
  15. Bowler, Peter J.; Morus, Iwan Rhys (2020). "The scientific revolution". Making Modern Science (2nd ed.). Chicago: University of Chicago Press. pp. 25–57. ISBN 978-0226365763.
  16. Bowler, Peter J.; Morus, Iwan Rhys (2020). "The chemical revolution". Making Modern Science (2nd ed.). Chicago: University of Chicago Press. pp. 58–82. ISBN 978-0226365763.
  17. Bowler, Peter J.; Morus, Iwan Rhys (2020). "The conservation of energy". Making Modern Science (2nd ed.). Chicago: University of Chicago Press. pp. 83–107. ISBN 978-0226365763.
  18. Bowler, Peter J.; Morus, Iwan Rhys (2020). "The age of the earth". Making Modern Science (2nd ed.). Chicago: University of Chicago Press. pp. 108–133. ISBN 978-0226365763.
  19. Bowler, Peter J.; Morus, Iwan Rhys (2020). "The Darwinian revolution". Making Modern Science (2nd ed.). Chicago, Illinois: University of Chicago Press. pp. 134–171. ISBN 978-0226365763.
  20. Cahan, David, ed. (2003). From Natural Philosophy to the Sciences: Writing the History of Nineteenth-Century Science. Chicago: University of Chicago Press. ISBN 978-0-226-08928-7.
  21. The Oxford English Dictionary dates the origin of the word "scientist" to 1834.
  22. Lightman, Bernard (2011). "Science and the Public". In Shank, Michael; Numbers, Ronald; Harrison, Peter (eds.). Wrestling with Nature. Chicago: University of Chicago Press. p. 367. ISBN 978-0-226-31783-0.
  23. Bowler, Peter J.; Morus, Iwan Rhys (2020). "Genetics". Making Modern Science (2nd ed.). Chicago: University of Chicago Press. pp. 197–221. ISBN 978-0226365763.
  24. Bowler, Peter J.; Morus, Iwan Rhys (2020). "Twentieth-century physics". Making Modern Science (2nd ed.). Chicago: University of Chicago Press. pp. 262–285. ISBN 978-0226365763.
  25. Bowler, Peter J.; Morus, Iwan Rhys (2020). "Introduction: Science, society, and history". Making Modern Science (2nd ed.). Chicago: University of Chicago Press. pp. 1–24. ISBN 978-0226365763.
  26. von Wright, Georg Henrik (25 October 2012) [1997]. "Progress: Fact and Fiction". In Burgen, Arnold; McLaughlin, Peter; Mittelstraß, Jürgen (eds.). The Idea of Progress. Philosophie und Wissenschaft - Volume 13 (reprint ed.). Berlin: Walter de Gruyter. p. 14. ISBN 9783110820423. Retrieved 13 October 2023. In historic reflections on art, cyclic schemas play a prominent role. This is a difference between art history and science history. The idea of linear progress simply does not apply in the esthetic domain.
  27. Kragh, Helge (1987). An introduction to the historiography of science. Cambridge [Cambridgeshire]: Cambridge University Press. ISBN 0-521-33360-1. OCLC 14692886.
  28. Bernard V. Lightman (2016). A companion to the history of science. Chichester (GB). ISBN 978-1-118-62077-9. OCLC 950521936.{{cite book}}: CS1 maint: location missing publisher (link)
  29. Golinski, Jan (22 July 2008) [1998]. Making Natural Knowledge: Constructivism and the History of Science. Cambridge history of science (revised ed.). Chicago: University of Chicago Press. p. 188. ISBN 9780226302324. Retrieved 13 October 2023. [...] historical writing [...] has largely abandoned the aim of telling a story of science's universal progress.
  30. Thomas, Norman (1961). Great Dissenters. Norton. p. 25. Retrieved 13 October 2023. [...] the brilliant Periclean Age, according to Dr. A. E. Taylor, witnessed one of the periodical bankruptcies of science [...].
  31. Poskett, James (2022). Horizons : a global history of science. [London]. ISBN 978-0-241-39409-0. OCLC 1235416152.{{cite book}}: CS1 maint: location missing publisher (link)
  32. Russel, C.A. (2002). Ferngren, G.B. (ed.). Science & Religion: A Historical Introduction. Johns Hopkins University Press. p. 7. ISBN 978-0-8018-7038-5. The conflict thesis, at least in its simple form, is now widely perceived as a wholly inadequate intellectual framework within which to construct a sensible and realistic historiography of Western science.
  33. Shapin, S. (1996). The Scientific Revolution. University of Chicago Press. p. 195. ISBN 978-0226750200. In the late Victorian period it was common to write about the 'warfare between science and religion' and to presume that the two bodies of culture must always have been in conflict. However, it is a very long time since these attitudes have been held by historians of science.
  34. Brooke, J. H. (1991). Science and Religion: Some Historical Perspectives. Cambridge University Press. p. 42. In its traditional forms, the conflict thesis has been largely discredited.
  35. Taliaferro, Charles (11 September 2014) [2009]. "Twentieth-century Philosophy of Religiion: An Introduction". In Oppy, Graham; Trakakis, N. N. (eds.). Twentieth-Century Philosophy of Religion. The History of Western Philosophy of Religion, Volume 5 (reprint ed.). Abingdon: Routledge. ISBN 9781317546382. Retrieved 13 October 2023. At the close of the twentieth century, proponents of the conflict thesis are well represented by Richard Dawkins, E. O. Wilson and Daniel Dennett.
  36. Shapin, Steven (2018). Leviathan and the air-pump : Hobbes, Boyle, and the experimental life. Princeton, N.J. ISBN 978-0-691-17816-5. OCLC 984327399.{{cite book}}: CS1 maint: location missing publisher (link)
  37. Schiebinger, Londa L. (2013). Nature's body : gender in the making of modern science (5th pbk. print ed.). New Brunswick, N.J.: Rutgers University Press. ISBN 978-0-8135-3531-9. OCLC 1048657291.
  38. Haraway, Donna Jeanne (1989). Primate visions : gender, race, and nature in the world of modern science. New York: Routledge. ISBN 978-1-136-60815-5. OCLC 555643149.
  39. Kohler, Robert E. (December 2007). "Finders, Keepers: Collecting Sciences and Collecting Practice". History of Science. 45 (4): 428–454. doi:10.1177/007327530704500403. ISSN 0073-2753. S2CID 147175644.
  40. Secord, Anne (December 1994). "Corresponding interests: artisans and gentlemen in nineteenth-century natural history". The British Journal for the History of Science. 27 (4): 383–408. doi:10.1017/S0007087400032416. ISSN 0007-0874. S2CID 144777485.
  41. Nasim, Omar W. (2013). Observing by hand : sketching the nebulae in the nineteenth century. Chicago. ISBN 978-0-226-08440-4. OCLC 868276095.{{cite book}}: CS1 maint: location missing publisher (link)
  42. Eddy, Matthew Daniel (2016). "The Interactive Notebook: How Students Learned to Keep Notes during the Scottish Enlightenment" (PDF). Book History. 19 (1): 86–131. doi:10.1353/bh.2016.0002. ISSN 1529-1499. S2CID 151427109. Archived (PDF) from the original on 15 June 2022. Retrieved 17 September 2022.
  43. Schaffer, Simon (1 June 1992). "Late Victorian metrology and its instrumentation: A manufactory of Ohms". In Bud, Robert; Cozzens, Susan E. (eds.). Invisible Connections: Instruments, Institutions, and Science. SPIE Conference Series. Vol. 10309. p. 1030904. Bibcode:1992SPIE10309E..04S. doi:10.1117/12.2283709. S2CID 115323404.
  44. Matsuoka, Yoshihiro; Vigouroux, Yves; Goodman, Major M.; Sanchez G., Jesus; Buckler, Edward; Doebley, John (30 April 2002). "A single domestication for maize shown by multilocus microsatellite genotyping". Proceedings of the National Academy of Sciences. 99 (9): 6080–6084. Bibcode:2002PNAS...99.6080M. doi:10.1073/pnas.052125199. PMC 122905. PMID 11983901.
  45. Sean B. Carroll (24 May 2010),"Tracking the Ancestry of Corn Back 9,000 Years" New York Times Archived 30 August 2017 at the Wayback Machine.
  46. Francesca Bray (1984), Science and Civilisation in China VI.2 Agriculture pp 299, 453 writes that teosinte, 'the father of corn', helps the success and vitality of corn when planted between the rows of its 'children', maize.
  47. Hoskin, Michael (2001). Tombs, Temples and their Orientations: a New Perspective on Mediterranean Prehistory. Bognor Regis, UK: Ocarina Books. ISBN 978-0-9540867-1-8.
  48. Ruggles, Clive (1999). Astronomy in Prehistoric Britain and Ireland. New Haven: Yale University Press. ISBN 978-0-300-07814-5.
  49. Perkins, Michael D. (2001). "Pharmacological Practices of Ancient Egypt". In W. A. Whitelaw (ed.). Proceedings of the 10th Annual History of Medicine Days (PDF). Calgary: Faculty of Medicine, The University of Calgary. pp. 5–11. hdl:1880/51835. Archived from the original (PDF) on 7 April 2008. Retrieved 9 March 2010.
  50. "Edwin Smith papyrus: Egyptian medical book". Encyclopædia Britannica. Archived from the original on 1 November 2014. Retrieved 21 December 2016.
  51. Lloyd, G.E.R. "The development of empirical research", in his Magic, Reason and Experience: Studies in the Origin and Development of Greek Science.
  52. McIntosh, Jane R. (2005). Ancient Mesopotamia: New Perspectives. Santa Barbara, California, Denver, Colorado, and Oxford, England: ABC-CLIO. pp. 273–276. ISBN 978-1-57607-966-9. Archived from the original on 5 February 2021. Retrieved 3 October 2020.
  53. Farber, Walter (1995). Witchcraft, Magic, and Divination in Ancient Mesopotamia. pp. 1891–1908. ISBN 978-0-684-19279-6. Retrieved 12 May 2018. {{cite book}}: |journal= ignored (help)
  54. Abusch, Tzvi (2002). Mesopotamian Witchcraft: Towards a History and Understanding of Babylonian Witchcraft Beliefs and Literature. Leiden, The Netherlands: Brill. p. 56. ISBN 978-90-04-12387-8. Archived from the original on 3 August 2020. Retrieved 7 May 2020.
  55. Brown, Michael (1995). Israel's Divine Healer. Grand Rapids, Michigan: Zondervan. p. 42. ISBN 978-0-310-20029-1. Archived from the original on 3 August 2020. Retrieved 7 May 2020.
  56. Biggs, R D. (2005). "Medicine, Surgery, and Public Health in Ancient Mesopotamia". Journal of Assyrian Academic Studies. 19 (1): 7–18.
  57. Heeßel, N. P. (2004). "Diagnosis, Divination, and Disease: Towards an Understanding of the Rationale Behind the Babylonian Diagonostic Handbook". In Horstmanshoff, H.F.J.; Stol, Marten; Tilburg, Cornelis (eds.). Magic and Rationality in Ancient Near Eastern and Graeco-Roman Medicine. Studies in Ancient Medicine. Vol. 27. Leiden, The Netherlands: Brill. pp. 97–116. ISBN 978-90-04-13666-3. Archived from the original on 3 August 2020. Retrieved 12 May 2018.
  58. Marten Stol (1993), Epilepsy in Babylonia, p. 55, Brill Publishers, ISBN 978-90-72371-63-8.
  59. Aaboe, A. (2 May 1974). "Scientific Astronomy in Antiquity". Philosophical Transactions of the Royal Society. 276 (1257): 21–42. Bibcode:1974RSPTA.276...21A. doi:10.1098/rsta.1974.0007. JSTOR 74272. S2CID 122508567.
  60. Paul Hoffman, The man who loved only numbers: the story of Paul Erdös and the search for mathematical truth, (New York: Hyperion), 1998, p. 187. ISBN 978-0-7868-6362-4
  61. Burkert, Walter (1 June 1972). Lore and Science in Ancient Pythagoreanism. Cambridge, Massachusetts: Harvard University Press. pp. 429, 462. ISBN 978-0-674-53918-1. Archived from the original on 29 January 2018. Retrieved 3 October 2020.
  62. Kahn, Charles H. (2001). Pythagoras and the Pythagoreans: A Brief History. Indianapolis, Indiana and Cambridge, England: Hackett Publishing Company. p. 32. ISBN 978-0-87220-575-8. Archived from the original on 31 March 2021. Retrieved 3 October 2020.
  63. Riedweg, Christoph (2005) [2002]. Pythagoras: His Life, Teachings, and Influence. Ithaca, New York: Cornell University Press. p. 27. ISBN 978-0-8014-7452-1. Archived from the original on 28 February 2022. Retrieved 3 October 2020.
  64. Joseph, George G. (2011). "The history of mathematics: Alternative perspectives". The Crest of the Peacock: Non-European Roots of Mathematics (3rd ed.). New Jersey: Princeton University Press. pp. 418–449. ISBN 978-0691135267.
  65. Sivin, Nathan (1985). "Why the Scientific Revolution did not take place in China – or did it?". The Environmentalist. 5 (1): 39–50. doi:10.1007/BF02239866. S2CID 45700796. Archived from the original on 8 June 2021. Retrieved 8 June 2021.
  66. Bartholomew, James R. (2003). "Asia". In Heilbron, John L. (ed.). The Oxford Companion to the History of Modern Science. New York: Oxford University Press. pp. 51–55. ISBN 978-0195112290.
  67. "3: Early Indian culture – Indus civilisation". st-and.ac.uk.
  68. Bisht, R.S. (1982). "Excavations at Banawali: 1974–77". In Possehl, Gregory L. (ed.). Harappan Civilization: A Contemporary Perspective. Oxford and IBH Publishing Co. pp. 113–124.
  69. Pickover, Clifford (2008). Archimedes to Hawking: laws of science and the great minds behind them. Oxford University Press US. p. 105. ISBN 978-0-19-533611-5. Archived from the original on 18 January 2017. Retrieved 7 May 2020.
  70. Mainak Kumar Bose, Late Classical India, A. Mukherjee & Co., 1988, p. 277.
  71. Ifrah, Georges. 1999. The Universal History of Numbers : From Prehistory to the Invention of the Computer, Wiley. ISBN 978-0-471-37568-5.
  72. O'Connor, J.J. and E.F. Robertson. 2000. 'Indian Numerals' Archived 29 September 2007 at the Wayback Machine, MacTutor History of Mathematics Archive, School of Mathematics and Statistics, University of St. Andrews, Scotland.
  73. George G. Joseph (1991). The crest of the peacock. London.
  74. Joseph, George G. (2011). "A Passage to Infinity: The Kerala Episode". The Crest of the Peacock: Non-European Roots of Mathematics (3rd ed.). New Jersey: Princeton University Press. pp. 418–449. ISBN 978-0691135267.
  75. Sarma, K.V. (2008). "Astronomy in India". In Selin, Helaine (ed.). Encyclopaedia of the History of Science, Technology, and Medicine in Non-Western Cultures. Springer, Dordrecht. pp. 317–321. doi:10.1007/978-1-4020-4425-0_9554. ISBN 978-1-4020-4425-0.
  76. Weiss, Richard S. (2009). "The invasion of utopia: The corruption of Siddha medicine by Ayurveda". Recipes for Immortality: Healing, Religion, and Community in South India. New York, New York: Oxford University Press. pp. 79–106. ISBN 978-0195335231.
  77. Coppa, A.; et al. (6 April 2006). "Early Neolithic tradition of dentistry: Flint tips were surprisingly effective for drilling tooth enamel in a prehistoric population". Nature. 440 (7085): 755–756. Bibcode:2006Natur.440..755C. doi:10.1038/440755a. PMID 16598247. S2CID 6787162.
  78. Mabbett, I.W. (1 April 1964). "The Date of the Arthaśāstra". Journal of the American Oriental Society. 84 (2): 162–169. doi:10.2307/597102. JSTOR 597102.
    Trautmann, Thomas R. (1971). Kauṭilya and the Arthaśāstra: A Statistical Investigation of the Authorship and Evolution of the Text. Brill. p. 10. while in his character as author of an arthaśāstra he is generally referred to by his gotra name, Kauṭilya.
  79. Mabbett 1964
    Trautmann 1971:5 "the very last verse of the work...is the unique instance of the personal name Viṣṇugupta rather than the gotra name Kauṭilya in the Arthaśāstra.
  80. Boesche, Roger (2002). The First Great Political Realist: Kautilya and His Arthashastra. Lexington Books. p. 17. ISBN 978-0-7391-0401-9.
  81. Needham (1986a), p. 208.
  82. Needham p422
  83. de Crespigny, Rafe. (2007). A Biographical Dictionary of Later Han to the Three Kingdoms (23–220 AD). Leiden: Koninklijke Brill, p. 1050. ISBN 90-04-15605-4.
  84. Morton, W. Scott and Charlton M. Lewis. (2005). China: Its History and Culture. New York: McGraw-Hill, Inc., p. 70. ISBN 0-07-141279-4.
  85. Minford & Lau (2002), 307; Balchin (2003), 26–27; Needham (1986a), 627; Needham (1986c), 484; Krebs (2003), 31.
  86. Needham (1986a), 626.
  87. Shen Kuo 沈括 (1086, last supplement dated 1091), Meng Ch'i Pi Than (夢溪筆談, Dream Pool Essays) as cited in Needham, Robinson & Huang 2004, p. 244
  88. Needham (1986c), pp. 111, 165, 445, 448, 456–457, 469–471.
  89. Agustín Udías, Searching the Heavens and the Earth: The History of Jesuit Observatories. (Dordrecht, The Netherlands: Kluwer Academic Publishers, 2003). p. 53
  90. Needham & Wang (1954), p. 581.
  91. Sambursky 1974, pp. 3, 37 called the pre-Socratics the transition from mythos to logos
  92. F.M. Cornford, Principium Sapientiae: The Origins of Greek Philosophical Thought, (Gloucester, Massachusetts, Peter Smith, 1971), p. 159.
  93. Arieti, James A. Philosophy in the ancient world: an introduction Archived 4 April 2023 at the Wayback Machine, p. 45. Rowman & Littlefield, 2005. 386 pp. ISBN 978-0-7425-3329-5.
  94. Dicks, D.R. (1970). Early Greek Astronomy to Aristotle. Cornell University Press. pp. 72–198. ISBN 978-0-8014-0561-7.
  95. O'Leary, De Lacy (1949). How Greek Science Passed to the Arabs. Routledge & Kegan Paul. ISBN 978-0-7100-1903-5.
  96. Leroi, Armand Marie (2015). The Lagoon: How Aristotle Invented Science. Bloomsbury. p. 7–. ISBN 978-1-4088-3622-4.
  97. Zalta, Edward N., ed. (2018). "Aristotle's Influence". Stanford Encyclopedia of Philosophy (Spring 2018 ed.).
  98. Barnes, Jonathan (1982). Aristotle: A Very Short Introduction. Oxford University Press. p. 86. ISBN 978-0-19-285408-7.
  99. Aristotle (7 January 2009). "De Caelo" [On the Heavens]. Translated by J. L. Stocks: The Internet Classics Archive. pp. 279 a17-30.
  100. Frede, Dorothea (1976). "On the Elements: Aristotle's Early Cosmology". Journal of the History of Philosophy. 14 (2): 227–229. doi:10.1353/hph.2008.0115. S2CID 144547689 via Project MUSE.
  101. Johnson, Monte (2004). "Review of The Order of Nature in Aristotle's Physics: Place and the Elements, Helen S. Lang". Isis. 95 (4): 687–688. doi:10.1086/432288. ISSN 0021-1753. JSTOR 10.1086/432288. Archived from the original on 4 December 2022. Retrieved 4 December 2022.
  102. G.E.R. Lloyd, Early Greek Science: Thales to Aristotle, (New York: W.W. Norton, 1970), pp. 144–146.
  103. Lloyd, G. E. R. Greek Science after Aristotle. New York: W.W. Norton & Co, 1973. ISBN 0-393-00780-4, p. 177.
  104. Greek Science, many editions, such as the paperback by Penguin Books. Copyrights in 1944, 1949, 1953, 1961, 1963. The first quote above comes from Part 1, Chapter 1; the second, from Part 2, Chapter 4.
  105. Marchant, Jo (2006). "In search of lost time". Nature. 444 (7119): 534–538. Bibcode:2006Natur.444..534M. doi:10.1038/444534a. PMID 17136067.
  106. Kleisiaris CF, Sfakianakis C, Papathanasiou IV. Health care practices in ancient Greece: The Hippocratic ideal. J Med Ethics Hist Med. 2014 Mar 15;7:6. PMID 25512827; PMCID: PMC4263393.
  107. Kleisiaris, Christos F.; Sfakianakis, Chrisanthos; Papathanasiou, Ioanna V. (15 March 2014). "Health care practices in ancient Greece: The Hippocratic ideal". Journal of Medical Ethics and History of Medicine. 7: 6. ISSN 2008-0387. PMC 4263393. PMID 25512827.
  108. DeHart, Scott M. (1999). "Hippocratic Medicine and the Greek Body Image". Perspectives on Science. 7 (3): 349–382. doi:10.1162/posc.1999.7.3.349. ISSN 1063-6145. S2CID 57571190.
  109. Casselman, Bill. "One of the Oldest Extant Diagrams from Euclid". University of British Columbia. Archived from the original on 4 June 2012. Retrieved 26 September 2008.
  110. Boyer (1991). "Euclid of Alexandria". A History of Mathematics. John Wiley & Sons. p. 119. ISBN 978-0471543978. The Elements of Euclid not only was the earliest major Greek mathematical work to come down to us, but also the most influential textbook of all times. [...]The first printed versions of the Elements appeared at Venice in 1482, one of the very earliest of mathematical books to be set in type; it has been estimated that since then at least a thousand editions have been published. Perhaps no book other than the Bible can boast so many editions, and certainly no mathematical work has had an influence comparable with that of Euclid's Elements.
  111. Calinger, Ronald (1999). A Contextual History of Mathematics. Prentice-Hall. p. 150. ISBN 978-0-02-318285-3. Shortly after Euclid, compiler of the definitive textbook, came Archimedes of Syracuse (c. 287–212 BC.), the most original and profound mathematician of antiquity.
  112. O'Connor, J.J.; Robertson, E.F. (February 1996). "A history of calculus". University of St Andrews. Archived from the original on 15 July 2007. Retrieved 7 August 2007.
  113. Lindberg, David C. (2007). "Roman and early medieval science". The Beginnings of Western Science (2nd ed.). Chicago: University of Chicago Press. pp. 132–162. ISBN 978-0-226-48205-7.
  114. Lindberg, David. (1992) The Beginnings of Western Science. University of Chicago Press. p. 363.
  115. Linda E. Voigts, "Anglo-Saxon Plant Remedies and the Anglo-Saxons", Isis, 70 (1979): 250–268; reprinted in Michael H. Shank, The Scientific Enterprise in Antiquity and the Middle Ages, Chicago: Univ. of Chicago Pr., 2000, pp. 163–181. ISBN 978-0-226-74951-8.
  116. Faith Wallis, Bede: The Reckoning of Time, Liverpool: Liverpool Univ. Pr., 2004, pp. xviii–xxxiv. ISBN 978-0-85323-693-1.
  117. Craig, Edward, ed. (1998). "Philoponus, John". Routledge Encyclopedia of Philosophy, Volume 7, Nihilism-Quantum mechanics. pp. 371–377, 373. ISBN 978-0-415-18712-1.
  118. Lindberg, David C. (2007). The Beginnings of Western Science: The European Scientific Tradition in Philosophical, Religious, and Institutional Context, Prehistory to A.D. 1450 (2nd ed.). Chicago: University of Chicago Press. pp. 307–308. ISBN 978-0-226-48205-7. Link to p. 307 Archived 3 August 2020 at the Wayback Machine from Google's copy of 2008 reprint.
  119. Duhem, Pierre (1913). "Physics, History of". In Herbermann, Charles G.; Pace, Edward A.; Pallen, Condé B.; Wynne, John J.; Shahan, Thomas J. (eds.). The Catholic Encyclopedia: An International Work of Reference on the Constitution, Doctrine, and History of the Catholic Church. Vol. 12. New York: Encyclopedia Press. p. 51. Archived from the original on 3 January 2014. Retrieved 19 April 2018.
  120. Lindberg, David. (1992) The Beginnings of Western Science. University of Chicago Press. p. 162.
  121. "John Philoponus". The Stanford Encyclopedia of Philosophy. Metaphysics Research Lab, Stanford University. 2018. Archived from the original on 22 April 2018. Retrieved 11 April 2018.
  122. Lindberg, David. (1992). The Beginnings of Western Science. University of Chicago Press. p. 162.
  123. Moosa, Ebrahim (6 April 2015). What Is a Madrasa?. UNC Press Books. ISBN 978-1-4696-2014-5. Archived from the original on 30 July 2022. Retrieved 25 November 2021.
  124. Barker, Peter (15 December 2017). "The Social Structure of Islamicate Science". Journal of World Philosophies. 2 (2). ISSN 2474-1795. Archived from the original on 24 November 2021. Retrieved 24 November 2021.
  125. "Süleymaniye Mosque, Turkey". www.architecturecourses.org. Archived from the original on 24 November 2021. Retrieved 24 November 2021.
  126. Toomer, Gerald (1990). "Al-Khwārizmī, Abu Jaʿfar Muḥammad ibn Mūsā". In Gillispie, Charles Coulston. Dictionary of Scientific Biography. 7. New York: Charles Scribner's Sons. ISBN 978-0-684-16962-0.
  127. Rosen, Edward (1985). "The Dissolution of the Solid Celestial Spheres". Journal of the History of Ideas. 46 (1): 19–21. doi:10.2307/2709773. JSTOR 2709773.
  128. Rabin, Sheila (2004). "Nicolaus Copernicus". Stanford Encyclopedia of Philosophy. Archived from the original on 15 July 2012. Retrieved 24 June 2012.
  129. Saliba, George (1994). A History of Arabic Astronomy: Planetary Theories During the Golden Age of Islam. New York University Press. pp. 254, 256–257. ISBN 978-0-8147-8023-7.
  130. Sameen Ahmed Khan Archived 5 March 2016 at the Wayback Machine, Arab Origins of the Discovery of the Refraction of Light; Roshdi Hifni Rashed (Picture) Awarded the 2007 King Faisal International Prize, Optics & Photonics News (OPN, Logo), Vol. 18, No. 10, pp. 22–23 (October 2007).
  131. Nasr, Seyyed Hossein (2007). "Avicenna". Encyclopædia Britannica Online. Archived from the original on 31 October 2007. Retrieved 3 June 2010.
  132. Jacquart, Danielle (2008). "Islamic Pharmacology in the Middle Ages: Theories and Substances". European Review (Cambridge University Press) 16: 219–227.
  133. David W. Tschanz, MSPH, PhD (August 2003). "Arab Roots of European Medicine", Heart Views 4 (2).
  134. Brater, D. Craig; Daly, Walter J. (2000). "Clinical pharmacology in the Middle Ages: Principles that presage the 21st century". Clinical Pharmacology & Therapeutics. 67 (5): 447–450 [448]. doi:10.1067/mcp.2000.106465. PMID 10824622. S2CID 45980791.
  135. Erica Fraser. The Islamic World to 1600, University of Calgary.
  136. Lindberg, David. (1992) The Beginnings of Western Science University of Chicago Press. p. 204.
  137. Numbers, Ronald (2009). Galileo Goes to Jail and Other Myths about Science and Religion. Harvard University Press. p. 45. ISBN 978-0-674-03327-6. Archived from the original on 20 January 2021. Retrieved 12 April 2018.
  138. "Debunking a myth". Harvard University. 7 April 2011. Archived from the original on 28 July 2019. Retrieved 12 April 2018.
  139. Love, Ronald S. (2006). "Historical overview". Maritime Exploration in the Age of Discovery, 1415–1800. Westport, Connecticut: Greenwood. pp. 1–8. ISBN 978-0313320439.
  140. William of Malmesbury, Gesta Regum Anglorum / The history of the English kings, ed. and trans. R.A.B. Mynors, R.M. Thomson, and M. Winterbottom, 2 vols., Oxford Medieval Texts (1998–99)
  141. R.W. Vernon, G. McDonnell and A. Schmidt, 'An integrated geophysical and analytical appraisal of early iron-working: three case studies' Historical Metallurgy 31(2) (1998), 72–75 79.
  142. David Derbyshire, Henry "Stamped Out Industrial Revolution", The Daily Telegraph (21 June 2002)
  143. Gal, Ofer (2021). "Medieval learning". The Origins of Modern Science. New York, New York: Cambridge University Press. pp. 101–138. ISBN 978-1316649701.
  144. Huff, Toby. Rise of early modern science 2nd ed. pp. 180–181
  145. Grant, Edward. "Science in the Medieval University", in James M. Kittleson and Pamela J. Transue, ed., Rebirth, Reform and Resilience: Universities in Transition, 1300–1700, Ohio State University Press, 1984, p. 68
  146. Thijssen, Hans (30 January 2003). "Condemnation of 1277". Stanford Encyclopedia of Philosophy. University of Stanford. Archived from the original on 11 March 2017. Retrieved 14 September 2009.
  147. "Rediscovering the Science of the Middle Ages". BioLogos. Archived from the original on 1 March 2023. Retrieved 26 October 2014.
  148. "023-A03: The Middle Ages and the Birth of Science – International Catholic University". International Catholic University. Archived from the original on 26 October 2014. Retrieved 26 October 2014.
  149. McLeish, Tom C. B.; Bower, Richard G.; Tanner, Brian K.; Smithson, Hannah E.; Panti, Cecilia; Lewis, Neil; Gasper, Giles E.M. (2014). "History: A medieval multiverse" (PDF). Nature News & Comment. 507 (7491): 161–163. doi:10.1038/507161a. PMID 24627918. Archived (PDF) from the original on 23 July 2018. Retrieved 15 July 2019.
  150. Edward Grant, The Foundations of Modern Science in the Middle Ages: Their Religious, Institutional, and Intellectual Contexts, (Cambridge Univ. Press, 1996), pp. 127–131.
  151. Edward Grant, A Source Book in Medieval Science, (Harvard Univ. Press, 1974), p. 232
  152. David C. Lindberg, Theories of Vision from al-Kindi to Kepler, (Chicago: Univ. of Chicago Pr., 1976), pp. 140–142.
  153. Edward Grant, The Foundations of Modern Science in the Middle Ages: Their Religious, Institutional, and Intellectual Contexts, (Cambridge: Cambridge Univ. Press, 1996), pp. 95–97.
  154. Edward Grant, The Foundations of Modern Science in the Middle Ages: Their Religious, Institutional, and Intellectual Contexts, (Cambridge Univ. Press, 1996), pp. 100–103.
  155. Szalay, Jessie (29 June 2016). "The Renaissance: The 'Rebirth' of Science & Culture". Historical development. LiveScience.com. Archived from the original on 27 October 2018. Retrieved 19 July 2019.
  156. Gottfried, Robert S. (1985). The Black Death: Natural & Human Disaster in Medieval Europe. Free Press. p. xiv. ISBN 978-0-02-912370-6. Archived from the original on 3 August 2020. Retrieved 19 July 2019.
  157. Allen Debus, Man and Nature in the Renaissance, (Cambridge: Cambridge Univ. Pr., 1978).
  158. Precise titles of these landmark books can be found in the collections of the Library of Congress. A list of these titles can be found in Bruno 1989
  159. See, for example, Heilbron 2003, pp. 741–744
  160. Schuster, John A. (1996) [1990]. "Scientific Revolution". In Cantor, Geoffrey; Olby, Robert; Christie, John; Hodge, Jonathon (eds.). Companion to the History of Modern Science. Abingdon, Oxfordshire: Routledge. pp. 217–242. ISBN 978-0415145787. Archived from the original on 27 September 2021. Retrieved 27 September 2021.
  161. Principe, Lawrence M. (2011). The Scientific Revolution: A Very Short Introduction. New York, NY: Oxford University Press. p. 47. ISBN 978-0-19-956741-6.
  162. Knox, Dilwyn (1999). "Ficino, Copernicus and Bruno on the Motion of the Earth". Bruniana & Campanelliana. 5 (2): 333–366. ISSN 1125-3819. JSTOR 24331708. Archived from the original on 4 December 2022. Retrieved 4 December 2022.
  163. Gingerich, Owen (1973). "From Copernicus to Kepler: Heliocentrism as Model and as Reality". Proceedings of the American Philosophical Society. 117 (6): 513–522. ISSN 0003-049X. JSTOR 986462.
  164. Neugebauer, O. (1945). "The History of Ancient Astronomy Problems and Methods". Journal of Near Eastern Studies. 4 (1): 20–23. doi:10.1086/370729. ISSN 0022-2968. JSTOR 542323. S2CID 39274542.
  165. Carman, Christián C. (2018). "The first Copernican was Copernicus: the difference between Pre-Copernican and Copernican heliocentrism". Archive for History of Exact Sciences. 72 (1): 1–20. doi:10.1007/s00407-017-0198-3. ISSN 0003-9519. JSTOR 45211937. S2CID 253894214. Archived from the original on 4 December 2022. Retrieved 4 December 2022.
  166. Newman, William R.; Mauskopf, Seymour H.; Eddy, Matthew Daniel (2014). Eddy, Matthew Daniel; Mauskopf, Seymour; Newman, William R. (eds.). "Chemical Knowledge in the Early Modern World". Osiris. 29: 1–15. doi:10.1086/678110. PMID 26103744. S2CID 29035688. Archived from the original on 30 July 2022. Retrieved 19 September 2014.
  167. Florin George Calian. Alkimia Operativa and Alkimia Speculativa. Some Modern Controversies on the Historiography of Alchemy.
  168. Hroncek, Susan (2017). "From Egyptian Science to Victorian Magic: On the Origins of Chemistry in Victorian Histories of Science". Victorian Review. 43 (2): 213–228. doi:10.1353/vcr.2017.0032. ISSN 1923-3280. S2CID 166044943. Archived from the original on 12 May 2021. Retrieved 28 April 2022.
  169. Power, d'Arcey. Life of Harvey. Longmans, Green, & co.
  170. Stanford (2003). "Ancient Theories of Soul". Plato.Stanford. Archived from the original on 7 August 2019. Retrieved 9 July 2018.
  171. Galen, David (1984). Galen on Respiration and the arteries. UCSC library: Princeton University Press. p. 201.
  172. Meyrick H. Carré, "The Formation of the Royal Society" History Today (Aug 1960) 10#8 pp 564–571.
  173. Heilbron (2003), p. 741.
  174. VanderVeer, Joseph B. (6 July 2011). "Hugh Williamson: Physician, Patriot, and Founding Father". Journal of the American Medical Association. 306 (1). doi:10.1001/jama.2011.933.
  175. Edwards, Paul (10 November 2021). "A Correction to the Record of Early Electrophysiology Research on the 250th Anniversary of a Historic Expedition to Île de Ré". HAL open-access archive. hal-03423498. Archived from the original on 6 May 2022. Retrieved 6 May 2022.
  176. Bresadola, Marco (15 July 1998). "Medicine and science in the life of Luigi Galvani". Brain Research Bulletin. 46 (5): 367–380. doi:10.1016/s0361-9230(98)00023-9. PMID 9739000. S2CID 13035403.
  177. Matthew Daniel Eddy (2008). The Language of Mineralogy: John Walker, Chemistry and the Edinburgh Medical School 1750–1800. Ashgate. Archived from the original on 3 September 2015. Retrieved 19 September 2014.
  178. Snyder, Laura J. (23 December 2000). "William Whewell". Stanford Encyclopedia of Philosophy. The Metaphysics Research Lab, Stanford University. Archived from the original on 4 January 2010. Retrieved 3 March 2008.
  179. Dobzhansky, Theodosius (1964). "Biology, Molecular and Organismic" (PDF). American Zoologist. 4 (4): 443–452. doi:10.1093/icb/4.4.443. PMID 14223586. Archived from the original (PDF) on 3 March 2016. Retrieved 5 February 2016.
  180. Campbell, Neil A.; Williamson, Brad; Heyden, Robin J. (2006). Biology: Exploring Life. Pearson Prentice Hall. ISBN 978-0-13-250882-7. OCLC 75299209. Archived from the original on 2 November 2014. Retrieved 9 September 2008.
  181. Guglielmo, Rinzivillo (18 May 2015). Natura, cultura e induzione nell'età delle scienze : fatti e idee del movimento scientifico in Francia e Inghilterra. Roma. pp. 79–. ISBN 978-88-6812-497-7. OCLC 913218837.{{cite book}}: CS1 maint: location missing publisher (link)
  182. Agar, Jon (2012). Science in the Twentieth Century and Beyond. Cambridge: Polity Press. ISBN 978-0-7456-3469-2.
  183. Alpher, Ralph A.; Herman, Robert (1948). "Evolution of the Universe". Nature. 162 (4124): 774–775. Bibcode:1948Natur.162..774A. doi:10.1038/162774b0. S2CID 4113488.
    Gamow, G. (1948). "The Evolution of the Universe". Nature. 162 (4122): 680–682. Bibcode:1948Natur.162..680G. doi:10.1038/162680a0. PMID 18893719. S2CID 4793163.
  184. "Wilson's 1978 Nobel lecture" (PDF). nobelprize.org. Archived (PDF) from the original on 13 April 2005. Retrieved 23 March 2005.
  185. Ronald K. Smeltzer. "Chien-Shiung Wu." Atomic Heritage Foundation, https://www.atomicheritage.org/profile/chien-shiung-wu Archived 15 September 2019 at the Wayback Machine. Accessed 26 Oct. 2017.
  186. Biography.com Editors. "Chien-Shiung Wu." Biography.com, 2 June 2016, https://www.biography.com/people/chien-shiung-wu-053116 Archived 26 October 2017 at the Wayback Machine.
  187. Garwin, Richard L.; Lee, Tsung‐Dao (1997). "Chien‐Shiung Wu". Physics Today. 50 (10): 120–122. doi:10.1063/1.2806727.
  188. Henig, Robin Marantz (2000). The Monk in the Garden : The Lost and Found Genius of Gregor Mendel, the Father of Genetics. Houghton Mifflin. ISBN 978-0-395-97765-1. OCLC 43648512.
  189. Watson, J. D.; Crick, F. H. C. (1953). "Molecular Structure of Nucleic Acids: A Structure for Deoxyribose Nucleic Acid" (PDF). Nature. 171 (4356): 737–738. Bibcode:1953Natur.171..737W. doi:10.1038/171737a0. PMID 13054692. S2CID 4253007. Archived from the original (PDF) on 24 October 2017.
  190. Erik Gregersen. "Cecilia Payne-Gaposchkin | American Astronomer." Encyclopædia Britannica, https://www.britannica.com/biography/Cecilia-Payne-Gaposchkin Archived 8 October 2018 at the Wayback Machine.
  191. Rachael Padman. "Cecilia Payne-Gaposchkin (1900–1979)." Newnham College Biographies, 2004, http://www.newn.cam.ac.uk/about/history/biographies/ Archived 25 March 2017 at the Wayback Machine.
  192. Cowan, W.M.; Harter, D.H.; Kandel, E.R. (2000). "The emergence of modern neuroscience: Some implications for neurology and psychiatry". Annual Review of Neuroscience. 23: 345–346. doi:10.1146/annurev.neuro.23.1.343. PMID 10845068.
  193. American Society of Mechanical Engineers. Karl Benz Archived 28 November 2021 at the Wayback Machine.
  194. Hecht, Jeff (10 August 2016). "The Bandwidth Bottleneck That is Throttling the Internet ". Scientific American.
  195. Handley, Lucy. "Nearly three quarters of the world will use just their smartphones to access the internet by 2025". CNBC. Archived from the original on 28 September 2022. Retrieved 28 September 2022.
  196. Overbye, Dennis (4 July 2012). "Physicists Find Particle That Could Be the Higgs Boson". The New York Times. Archived from the original on 7 June 2021. Retrieved 7 June 2021.

Sources

Further reading

  • Agar, Jon (2012) Science in the Twentieth Century and Beyond, Polity Press. ISBN 978-0-7456-3469-2.
  • Agassi, Joseph (2007) Science and Its History: A Reassessment of the Historiography of Science (Boston Studies in the Philosophy of Science, 253) Springer. ISBN 978-1-4020-5631-4.
  • Boorstin, Daniel (1983). The Discoverers : A History of Man's Search to Know His World and Himself. Random House. ISBN 978-0-394-40229-1. OCLC 9645583.
  • Bowler, Peter J. (1993) The Norton History of the Environmental Sciences.
  • Brock, W.H. (1993) The Norton History of Chemistry.
  • Bronowski, J. (1951) The Common Sense of Science Heinemann. ISBN 978-84-297-1380-0.) (Includes a description of the history of science in England.)
  • Byers, Nina and Gary Williams, ed. (2006) Out of the Shadows: Contributions of Twentieth-Century Women to Physics, Cambridge University Press ISBN 978-0-521-82197-1
  • Herzenberg, Caroline L. (1986). Women Scientists from Antiquity to the Present Locust Hill Press ISBN 978-0-933951-01-3
  • Kuhn, Thomas S. (1996). The Structure of Scientific Revolutions (3rd ed.). University of Chicago Press. ISBN 978-0-226-45807-6.
  • Kumar, Deepak (2006). Science and the Raj: A Study of British India, 2nd edition. Oxford University Press. ISBN 978-0-19-568003-4
  • Lakatos, Imre (1978). History of Science and its Rational Reconstructions published in The Methodology of Scientific Research Programmes: Philosophical Papers Volume 1. Cambridge University Press
  • Levere, Trevor Harvey. (2001) Transforming Matter: A History of Chemistry from Alchemy to the Buckyball
  • Lindberg, David C.; Shank, Michael H., eds. (2013). Medieval Science. The Cambridge History of Science. Vol. 2. Cambridge University Press. doi:10.1017/CHO9780511974007. ISBN 978-0-521-59448-6.
  • Lipphardt, Veronika/Ludwig, Daniel, Knowledge Transfer and Science Transfer, EGO – European History Online, Mainz: Institute of European History, 2011, retrieved: March 8, 2020 (pdf).
  • Margolis, Howard (2002). It Started with Copernicus. McGraw-Hill. ISBN 978-0-07-138507-7
  • Mayr, Ernst. (1985). The Growth of Biological Thought: Diversity, Evolution, and Inheritance.
  • North, John. (1995). The Norton History of Astronomy and Cosmology.
  • Nye, Mary Jo, ed. (2002). The Cambridge History of Science, Volume 5: The Modern Physical and Mathematical Sciences
  • Park, Katharine, and Lorraine Daston, eds. (2006) The Cambridge History of Science, Volume 3: Early Modern Science
  • Porter, Roy, ed. (2003). The Cambridge History of Science, Volume 4: The Eighteenth Century
  • Rousseau, George and Roy Porter, eds. 1980). The Ferment of Knowledge: Studies in the Historiography of Science Cambridge University Press. ISBN 978-0-521-22599-1
  • Slotten, Hugh Richard, ed. (2014) The Oxford Encyclopedia of the History of American Science, Medicine, and Technology.
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