Greenhouse

A greenhouse is a structure that allows people to regulate climatic conditions, such as temperature and humidity. There are many different designs of greenhouses; however, in general these buildings include large areas of transparent material to capture the light and heat of the sun. The three most common transparent materials used in the roof and walls of modern greenhouses are rigid plastics made of polycarbonate, plastic films made of polyethylene or glass panes.[1] When the interior of a greenhouse is exposed to sunlight, the internal temperature rises and shelters the plants from cold weather.

Victoria amazonica (giant Amazon waterlilies) in a large greenhouse at the Saint Petersburg Botanical Garden

The word greenhouse can be used interchangeably with the terms glasshouse and hothouse, depending on the building's material and heating system. Buildings today are more commonly referred to as greenhouses because they can be constructed of a variety of materials, like wood and polyethylene plastic.[2] A glasshouse, on the other hand, is a more traditional style of greenhouse that is only constructed with panes of glass to allow light into the building.[2] The term hothouse implies that the greenhouse is heated through artificial means; however, both heated and unheated structures can be defined generally as greenhouses.

Young tomato plants for transplanting in an industrial-sized greenhouse in the Netherlands

Greenhouses can range in size from small sheds to industrial-sized buildings and enormous glasshouses. The smallest example is a miniature greenhouse known as a cold frame, typically used at home, whereas large commercial greenhouses are high tech production facilities for vegetables, flowers or fruits. The glass greenhouses are filled with equipment including screening installations, heating, cooling, and lighting, and may be controlled by a computer to optimize conditions for plant growth. Different techniques are then used to manage growing conditions, including air temperature, relative humidity and vapour-pressure deficit, in order to provide the optimum environment for cultivation of a specific crop.

History

Cucumbers reached to the ceiling in a greenhouse in Richfield, Minnesota, where market gardeners grew a wide variety of produce for sale in Minneapolis, c.1910

Roman Empire

Before the development of greenhouses, agricultural practices were constrained to weather conditions. According to the climatic zone of communities, people were limited to a select range of species and time of the year in which they could grow plants. Yet around 30 CE, the Roman Empire built the first recorded attempt of an artificial environment.[3] Due to emperor Tiberius's declining health, the royal physicians recommended that the emperor eat one cucumber a day.[3] Cucumbers, however, are quite tender plants and do not grow easily year-round. Therefore, the Romans designed an artificial environment, like a greenhouse, to have cucumbers available for the emperor all year. Cucumbers were planted in wheeled carts which were put in the sun daily, then taken inside to keep them warm at night. The cucumbers were stored under frames or in cucumber houses glazed with either oiled cloth known as specularia or with sheets of selenite (a.k.a. lapis specularis), according to the description by Pliny the Elder.[4][5]

15th-century Korea

The next biggest breakthrough in greenhouse design came from Korea in the 15th century during the Joseon dynasty. In the 1450s, Soon ui Jeon described the first artificially heated greenhouse in his manuscript called Sangayorok.[6] Soon ui Jeon was a physician to the royal family, and Sangayorok was intended to provide the nobility with important agricultural and housekeeping knowledge.[6] Within the section of agricultural techniques, Soon ui Jeon wrote how to build a greenhouse that was able to cultivate vegetables and other plants in the winter.[6] The Korean design adds an ondol system to the structure.[6] An ondol is a Korean heating system used in domestic spaces, which runs a flue pipe from a heat source underneath the flooring.[6] In addition to the ondol, a cauldron filled with water was also heated to create steam and increase the temperature and humidity in the greenhouse.[6] These Korean greenhouses were the first active greenhouses that controlled temperature, rather than only relying on energy from the sun.[2] The design still included passive heating methods, such as semi-transparent oiled hanji windows to capture light and cob walls to retain heat, but the furnace provided extra control over the artificial environment.[6] The Annals of the Joseon Dynasty confirm that greenhouse-like structures incorporating ondol were constructed to provide heat for mandarin orange trees during the winter of 1438.[6]

17th century

The concept of greenhouses also appeared in the Netherlands and then England in the 17th century, along with the plants. Some of these early attempts required enormous amounts of work to close up at night or to winterize. There were serious problems with providing adequate and balanced heat in these early greenhouses. The first 'stove' (heated) greenhouse in the UK was completed at Chelsea Physic Garden by 1681.[7] Today, the Netherlands has many of the largest greenhouses in the world, some of them so vast that they are able to produce millions of vegetables every year.

Experimentation with greenhouse design continued during the 17th century in Europe, as technology produced better glass and construction techniques improved. The greenhouse at the Palace of Versailles was an example of their size and elaborateness; it was more than 150 metres (490 ft) long, 13 metres (43 ft) wide, and 14 metres (46 ft) high.

19th-century

A heated greenhouse, or "hothouse", In Macon, Georgia c.1877.
Interior of a "hothouse" (or greenhouse) in Central City Park, Macon, GA, c.1877.

The French botanist Charles Lucien Bonaparte is often credited with building the first practical modern greenhouse in Leiden, Holland, during the 1800s to grow medicinal tropical plants.[8] Originally only on the estates of the rich, the growth of the science of botany caused greenhouses to spread to the universities. The French called their first greenhouses orangeries, since they were used to protect orange trees from freezing. As pineapples became popular, pineries, or pineapple pits, were built.

19th-century England

The Royal Greenhouses of Laeken, Brussels, Belgium, an example of 19th-century greenhouse architecture

The largest glasshouses yet conceived were constructed in England during the Victorian era. As a direct result of colonial expansion, the purpose of glasshouses changed from agriculture to horticulture.[9] The accelerated transfer of plants and horticultural knowledge between colonies contributed to the Victorian fascination with 'exotic' plants and environments.[10] Glasshouses became spectacles to entertain the general public. The curated environments in glasshouses aimed to capture "the Western imagination of an idealised landscape" and support the fantasy of the cultural 'other'.[10] As a consequence, the collection of plants are believed to be true reflections of the world, yet are actually stereotypical arrangements of 'exotic' plants to symbolize exactly where British colonies are and how far their authority reaches.[9] To uphold British hegemony, glasshouses became arguments of colonial power which flaunt the "absolute control of colonized environments and flora...[using plants] as a symbol of British Imperial power.[11]

A prominent design from the 19th century were glasshouses with sufficient height for sizeable trees, called palm houses. These were normally in public gardens or parks and exemplified the 19th-century development of glass and iron architecture. This technology was widely used in railway stations, markets, exhibition halls, and other large buildings that needed large, open internal area. One of the earliest examples of a palm house is in the Belfast Botanic Gardens. Designed by Charles Lanyon, the building was completed in 1840. It was constructed by iron-maker Richard Turner, who would later build the Palm House, Kew Gardens at the Royal Botanic Gardens, Kew, London, in 1848. This came shortly after the Chatsworth Great Conservatory (1837-40) and shortly before The Crystal Palace (1851), both designed by Joseph Paxton, and both now lost.[12]

Other large greenhouses built in the 19th century included the New York Crystal Palace, Munich's Glaspalast and the Royal Greenhouses of Laeken (1874–1895) for King Leopold II of Belgium. In Japan, the first greenhouse was built in 1880 by Samuel Cocking, a British merchant who exported herbs.

20th century

A plastic air-insulated greenhouse in New Zealand
Giant greenhouses in Westland, the Netherlands

In the 20th century, the geodesic dome was added to the many types of greenhouses. Notable examples are the Eden Project in Cornwall, The Rodale Institute[13] in Pennsylvania, the Climatron at the Missouri Botanical Garden in St. Louis, Missouri, and Toyota Motor Manufacturing Kentucky.[14] The pyramid is another popular shape for large, high greenhouses; there are several pyramidal greenhouses at the Muttart Conservatory in Alberta (c.1976).

Greenhouse structures adapted in the 1960s when wider sheets of polyethylene (polythene) film became widely available. Hoop houses were made by several companies and were also frequently made by the growers themselves. Constructed of aluminum extrusions, special galvanized steel tubing, or even just lengths of steel or PVC water pipe, construction costs were greatly reduced. This resulted in many more greenhouses being constructed on smaller farms and garden centers. Polyethylene film durability increased greatly when more effective UV-inhibitors were developed and added in the 1970s; these extended the usable life of the film from one or two years up to three and eventually four or more years.

Gutter-connected greenhouses became more prevalent in the 1980s and 1990s. These greenhouses have two or more bays connected by a common wall, or row of support posts. Heating inputs were reduced as the ratio of floor area to exterior wall area was increased substantially. Gutter-connected greenhouses are now commonly used both in production and in situations where plants are grown and sold to the public as well. Gutter-connected greenhouses are commonly covered with structured polycarbonate materials, or a double layer of polyethylene film with air blown between to provide increased heating efficiencies.

Theory of operation

The warmer temperature in a greenhouse occurs because incident solar radiation passes through the transparent roof and walls and is absorbed by the floor, earth, and contents, which become warmer. These in turn warm up the surrounding air within the greenhouse. As the structure is not open to the atmosphere, the warmed air cannot escape via convection due to the presence of roof and walls, so the temperature inside the greenhouse rises.

This differs from the earth-oriented theory known as the "greenhouse effect",[15][16][17][18], which is a reduction in a planet's heat loss through radiation.

Quantitative studies suggest that the effect of infrared radiative cooling is not negligibly small, and may have economic implications in a heated greenhouse. Analysis of issues of near-infrared radiation in a greenhouse with screens of a high coefficient of reflection concluded that installation of such screens reduced heat demand by about 8%, and application of dyes to transparent surfaces was suggested. Composite less-reflective glass, or less effective but cheaper anti-reflective coated simple glass, also produced savings.[19]

Ventilation

Ventilation is one of the most important components in a successful greenhouse. If there is no proper ventilation, greenhouses and their growing plants can become prone to problems. The main purposes of ventilation is to regulate the temperature and humidity to the optimal level, and to ensure movement of air and thus prevent the build-up of plant pathogens (such as Botrytis cinerea) that prefer still air conditions. Ventilation also ensures a supply of fresh air for photosynthesis and plant respiration, and may enable important pollinators to access the greenhouse crop.

Ventilation can be achieved via the use of vents – often controlled automatically via a computer – and recirculation fans.

Heating

Thermal lights at a greenhouse in Närpes, Finland

Heating or electricity is one of the most considerable costs in the operation of greenhouses across the globe, especially in colder climates. The main problem with heating a greenhouse as opposed to a building that has solid opaque walls is the amount of heat lost through the greenhouse covering. Since the coverings need to allow light to filter into the structure, they conversely cannot insulate very well. With traditional plastic greenhouse coverings having an R-value of around 2, a great amount of money is therefore spent to continually replace the heat lost. Most greenhouses, when supplemental heat is needed use natural gas or electric furnaces.

Passive heating methods exist which seek heat using low energy input. Solar energy can be captured from periods of relative abundance (day time/summer), and released to boost the temperature during cooler periods (night time/winter). Waste heat from livestock can be used to heat greenhouses, e.g., placing a chicken coop inside a greenhouse recovers the heat generated by the chickens, which would otherwise be wasted.[20] Some greenhouses also rely on geothermal heating.[21]

Cooling

Cooling is typically done by opening windows in the greenhouse when it gets too warm for the plants inside it. This can be done manually, or in an automated manner. Window actuators can open windows due to temperature difference or can be opened by electronic controllers. Electronic controllers are often used to monitor the temperature and adjusts the furnace operation to the conditions. This can be as simple as a basic thermostat, but can be more complicated in larger greenhouse operations.

For very hot situations, a shade house providing cooling by shade may be used.

Lighting

During the day, light enters the greenhouse via the windows and is used by the plants. Some greenhouses are also equipped with grow lights (often LED lights) which are switched on at night to increase the amount of light the plants get, hereby increasing the yield with certain crops.[22]

Carbon dioxide enrichment

The benefits of carbon dioxide enrichment to about 1100 parts per million in greenhouse cultivation to enhance plant growth has been known for nearly 100 years.[23][24][25] After the development of equipment for the controlled serial enrichment of carbon dioxide, the technique was established on a broad scale in the Netherlands.[26] Secondary metabolites, e.g., cardiac glycosides in Digitalis lanata, are produced in higher amounts by greenhouse cultivation at enhanced temperature and at enhanced carbon dioxide concentration.[27] Carbon dioxide enrichment can also reduce greenhouse water usage by a significant fraction by mitigating the total air-flow needed to supply adequate carbon for plant growth and thereby reducing the quantity of water lost to evaporation.[28] Commercial greenhouses are now frequently located near appropriate industrial facilities for mutual benefit. For example, Cornerways Nursery in the UK is strategically placed near a major sugar refinery,[29] consuming both waste heat and CO2 from the refinery which would otherwise be vented to atmosphere. The refinery reduces its carbon emissions, whilst the nursery enjoys boosted tomato yields and does not need to provide its own greenhouse heating.

Enrichment only becomes effective where, by Liebig's law, carbon dioxide has become the limiting factor. In a controlled greenhouse, irrigation may be trivial, and soils may be fertile by default. In less-controlled gardens and open fields, rising CO2 levels only increase primary production to the point of soil depletion (assuming no droughts,[30][31][32] flooding,[33] or both[34][35][36][37][38]), as demonstrated prima facie by CO2 levels continuing to rise. In addition, laboratory experiments, free air carbon enrichment (FACE) test plots,[39][40] and field measurements provide replicability.[41][42]

Types

Private greenhouse in Finland.

In domestic greenhouses, the glass used is typically 3mm (or ⅛″) 'horticultural glass' grade, which is good quality glass that should not contain air bubbles (which can produce scorching on leaves by acting like lenses).[43]

Plastics mostly used are polyethylene film and multiwall sheets of polycarbonate material, or PMMA acrylic glass.

Commercial glass greenhouses are often high-tech production facilities for vegetables or flowers. The glass greenhouses are filled with equipment such as screening installations, heating, cooling and lighting, and may be automatically controlled by a computer.

Dutch Light

In the UK and other Northern European countries a pane of horticultural glass referred to as "Dutch Light" was historically used as a standard unit of construction, having dimensions of 28¾″ x 56″ (approx. 730 mm x 1422 mm). This size gives a larger glazed area when compared with using smaller panes such as the 600 mm width typically used in modern domestic designs which then require more supporting framework for a given overall greenhouse size. A style of greenhouse having sloped sides (resulting in a wider base than at eaves height) and using these panes uncut is also often referred to as of "Dutch Light design", and a cold frame using a full- or half-pane as being of "Dutch" or "half-Dutch" size.

Greenhouses with spectrally selective solar modules

Potential new photovoltaic technologies which let through the colors of light needed by the interior plants, but use the other wavelengths to generate electricity, might one day have some future use in greenhouses. There are prototypes of such greenhouses.[44][45] "Semi-transparent" PV panels used in agrivoltaics increase the spacing between solar cells and use clear backsheets enhancing food production below. In this option, the fixed PV panels enable the east–west movement of the sun to "spray sunlight" over the plants below, thereby reducing "over-exposure" due to the day-long sun as in transparent greenhouses, as they generate electricity above.[46]

Uses

Greenhouses allow for greater control over the growing environment of plants. Depending upon the technical specification of a greenhouse, key factors which may be controlled include temperature, levels of light and shade, irrigation, fertilizer application, and atmospheric humidity. Greenhouses may be used to overcome shortcomings in the growing qualities of a piece of land, such as a short growing season or poor light levels, and they can thereby improve food production in marginal environments. Shade houses are used specifically to provide shade in hot, dry climates.[47][48]

As they may enable certain crops to be grown throughout the year, greenhouses are increasingly important in the food supply of high-latitude countries. One of the largest complexes in the world is in Almería, Andalucía, Spain, where greenhouses cover almost 200 km2 (49,000 acres).[49]

Greenhouses are often used for growing flowers, vegetables, fruits, and transplants. Special greenhouse varieties of certain crops, such as tomatoes, are generally used for commercial production.

Many vegetables and flowers can be grown in greenhouses in late winter and early spring, and then transplanted outside as the weather warms. Seed tray racks can also be used to stack seed trays inside the greenhouse for later transplanting outside. Hydroponics (especially hydroponic A-frames) can be used to make the most use of the interior space when growing crops to mature size inside the greenhouse.

Bumblebees can be used as pollinators for pollination, but other types of bees have also been used, as well as artificial pollination.

The relatively closed environment of a greenhouse has its own unique management requirements, compared with outdoor production. Pests and diseases, and extremes of temperature and humidity, have to be controlled, and irrigation is necessary to provide water. Most greenhouses use sprinklers or drip lines. Significant inputs of heat and light may be required, particularly with winter production of warm-weather vegetables.

Greenhouses also have applications outside of the agriculture industry. GlassPoint Solar, located in Fremont, California, encloses solar fields in greenhouses to produce steam for solar-enhanced oil recovery. For example, in November 2017 GlassPoint announced that it is developing a solar enhanced oil recovery facility near Bakersfield, CA that uses greenhouses to enclose its parabolic troughs.[50]

An "alpine house" is a specialized greenhouse used for growing alpine plants. The purpose of an alpine house is to mimic the conditions in which alpine plants grow; particularly to provide protection from wet conditions in winter. Alpine houses are often unheated, since the plants grown there are hardy, or require at most protection from hard frost in the winter. They are designed to have excellent ventilation.[51]

Adoption

Worldwide, there are an estimated nine million acres of greenhouses.[52]

Netherlands

Greenhouses in the Westland region.

The Netherlands has some of the largest greenhouses in the world. Such is the scale of food production in the country that in 2017, greenhouses occupied nearly 5,000 hectares.[53]

Greenhouses began to be built in the Westland region of the Netherlands in the mid-19th century. The addition of sand to bogs and clay soil created fertile soil for agriculture, and around 1850, grapes were grown in the first greenhouses, simple glass constructions with one of the sides consisting of a solid wall. By the early 20th century, greenhouses began to be constructed with all sides built using glass, and they began to be heated. This also allowed for the production of fruits and vegetables that did not ordinarily grow in the area. Today, the Westland and the area around Aalsmeer have the highest concentration of greenhouse agriculture in the world. The Westland produces mostly vegetables, besides plants and flowers; Aalsmeer is noted mainly for the production of flowers and potted plants. Since the 20th century, the area around Venlo and parts of Drenthe have also become important regions for greenhouse agriculture.

Since 2000, technical innovations include the "closed greenhouse", a completely closed system allowing the grower complete control over the growing process while using less energy. Floating greenhouses are used in watery areas of the country.

The Netherlands has around 4,000 greenhouse enterprises that operate over 9,000 hectares[54] of greenhouses and employ some 150,000 workers, producing €7.2 billion[55] worth of vegetables, fruit, plants, and flowers, some 80% of which is exported.[56][57]

See also

Citations

  1. "How To Choose A Glazing Material For A Year Round Greenhouse". Ceres Greenhouse Solutions. 3 July 2017. Retrieved 4 April 2023.
  2. "Way Back When: A History Of The English Glasshouse". Hartley Botanic. 3 September 2015. Retrieved 4 April 2023.
  3. Crumpacker, Mark (27 June 2019). "A Look Back At The Amazing History Of Greenhouses". Medium. Retrieved 4 April 2023.
  4. Note:
    • Pliny the Elder with John Bostock and H. T. Riley, trans., Natural History (London, England: Henry G. Bohn, 1856), vol. 4, book 19, chapter 23: "Vegetables of a cartilaginous nature – cucumbers. Pepones.", p. 156.
    • The Roman poet Martial also briefly mentions greenhouses or cold frames in: Martial with Walter C. A. Ker, trans., Epigrams (London: William Heinemann, 1920), vol. 2, book 8 (VIII ), no. 14 (XIV), p. 13.
  5. rogue classicism: Roman Greenhouses? Cartilaginum generis extraque terram est cucumis mira voluptate Tiberio principi expetitus Nullo quippe non die contigit ei pensiles eorum hortos promoventibus in solem rotis olitoribus rursusque hibernis diebus intra specularium munimenta revocantibus
  6. Yoon, Sang Jun; Woudstra, Jan (Summer 2007). "Advanced Horticultural Techniques in Korea: The Earliest Documented Greenhouses". Garden History. 35 (1): 68–84. JSTOR 25472355.
  7. Minter, Sue (2003). The Apothecaries' Garden. Sutton. p. 4. ISBN 978-0750936385.
  8. "Cambridge Glasshouse". Newport, North Humberside. Archived from the original on 9 May 2013. Retrieved 10 July 2016.
  9. Edwin (27 April 2021). "The Great Palm House At Kew Gardens London, England 1848-An Encyclopedia Of Architecture and Colonialism". University of British Columbia. Retrieved 4 April 2023.
  10. Evans, Evie. "Cultivating Colonialism: The Musealisation Of Natural Object In the Hortus Botanicus, Amsterdam, And The Royal Botanic Gardens, Kew." (Master's thesis, University of Amsterdam, 2021). FramerFramed.
  11. Lynden (26 April 2021). "The Palm House At Kew Gardens: Iron, Climate Control And Commercialism-An Encyclopedia of Architecture And Colonialism". University of British Columbia. Retrieved 4 April 2023.
  12. Pevsner, 235, 238-241
  13. "A dome grows in our garden". Archived from the original on 10 June 2013. Retrieved 9 May 2013.
  14. "Rounding Out the Waste Cycle: TMMK's On-Site Greenhouse". TMMK and the Environment. Archived from the original on 18 September 2013. Retrieved 7 November 2013.
  15. A Dictionary of Physics (6 ed.), Oxford University Press, 2009, ISBN 9780199233991: "greenhouse effect"
  16. A Dictionary of Chemistry (6 ed.), edited by John Daintith, Oxford University Press, 2008, ISBN 9780199204632: "greenhouse effect"
  17. Wood, RW (1909). "Note on the theory of the greenhouse". Philosophical Magazine. 17: 319–320.
  18. Shmaefsky, Brian (2004). Favorite demonstrations for college science: an NSTA Press journals collection. NSTA Press. p. 57. ISBN 978-0-87355-242-4.
  19. Sławomir Kurpaska (2014). "Energy Effects During Using the Glass with Different Properties in a Heated Greehouse" (PDF). Technical Sciences. 17 (4): 351–360. Archived (PDF) from the original on 9 October 2022.
  20. "To Heat a Greenhouse, Add Some Chickens - GOOD". www.good.is. Retrieved 18 September 2023.
  21. Gerlock, Grant (11 February 2016). "Citrus In The Snow: Geothermal Greenhouses Grow Local Produce In Winter". NPR.
  22. Tewolde, FT; Lu, N; Shiina, K; Maruo, T; Takagaki, M; Kozai, T; Yamori, W (2016). "Nighttime Supplemental LED Inter-lighting Improves Growth and Yield of Single-Truss Tomatoes by Enhancing Photosynthesis in Both Winter and Summer". Front Plant Sci. 7: 448. doi:10.3389/fpls.2016.00448. PMC 4823311. PMID 27092163.
  23. Reinau, E. (1927) Praktische Kohlensäuredüngung, Springer, Berlin
  24. Brijer, C. J. (1959) "Een verlaten goudmijn: koolzuurbemesting". In: Mededelingenvan de DirectieTuinbouw. Ministerie van Landbouw en Visserij, Nederland. Vol. 22, pp. 670–674
  25. Wittwer S. H. (1986). "Worldwide status and history of CO2 enrichment – an overview.". In Enoch, H.Z.; Kimbal, B.A. (eds.). Carbon dioxide enrichment of greenhouse crops, Vol. I: Status and CO2 Sources. Boca Raton, Fla.: CRC Press.
  26. Wittwer, SH; Robb, WM (1964). "Carbon dioxide enrichment of greenhouse atmospheres for food crop production". Economic Botany. 18: 34–56. doi:10.1007/bf02904000. S2CID 40257734.
  27. Stuhlfauth, T.; Fock, HP (1990). "Effect of whole season CO2 enrichment on the cultivation of a medicinal plant, Digitalis lanata". Journal of Agronomy and Crop Science. 164 (3): 168–173. doi:10.1111/j.1439-037x.1990.tb00803.x.
  28. Stacey, Neil; Fox, James; Hildebrandt, Diane (20 February 2018). "Reduction in greenhouse water usage through inlet CO2 enrichment". AIChE Journal. 64 (7): 2324–2328. doi:10.1002/aic.16120.
  29. "Products and Services, tomatoes". Archived from the original on 24 June 2016. Retrieved 10 July 2016.
  30. Buis, A (23 April 2014). "NASA Finds Drought May Take Toll on Congo Rainforest". Jet Propulsion Laboratory. Retrieved 17 May 2015.
  31. Buis, A (17 January 2013). "Study Finds Severe Climate Jeopardizing Amazon Forest". Jet Propulsion Laboratory. Retrieved 17 May 2015.
  32. Cook, BI; Ault, TR; Smerdon, JE (12 February 2015). "Unprecedented 21st century drought risk in the American Southwest and Central Plains". Science Advances. 1 (1): e1400082. Bibcode:2015SciA....1E0082C. doi:10.1126/sciadv.1400082. PMC 4644081. PMID 26601131.
  33. Marshall, Claire (5 March 2015). "Global flood toll to triple by 2030". BBC. Retrieved 17 May 2015.
  34. Law, Beverly. "Carbon sequestration estimate in US increased – barring a drought". www.eurekalert.org. AAAS. Retrieved 17 May 2015.
  35. Xiao, J; et al. (April 2011). "Assessing net ecosystem carbon exchange of U.S. terrestrial ecosystems by integrating eddy covariance flux measurements and satellite observations". Agricultural and Forest Meteorology. 151 (1): 60–69. Bibcode:2011AgFM..151...60X. doi:10.1016/j.agrformet.2010.09.002. S2CID 5020848.
  36. Famiglietti, J.; Rodell, M. (14 June 2013). "Water in the Balance". Environmental Science. 340 (6138): 1300–1301. Bibcode:2013Sci...340.1300F. doi:10.1126/science.1236460. PMID 23766323. S2CID 188474796.
  37. Freeman, Andrew (22 May 2015). "Weather Whiplash: Texas Goes From Extreme Drought to Floods in 3 Weeks". Mashable.com. Retrieved 30 May 2015.
  38. Schwartz, John (27 May 2015). "Scientists Warn to Expect More Weather Extremes". New York Times. Retrieved 30 May 2015.
  39. Soil fertility limits forests' capacity to absorb excess CO2, 18 May 2001
  40. Schlesinger, W.; Lichter, J. (24 May 2001). "Limited carbon storage in soil and litter of experimental forest plots under increased atmospheric CO2". Nature. 411 (6836): 466–469. Bibcode:2001Natur.411..466S. doi:10.1038/35078060. PMID 11373676. S2CID 4391335.
  41. Phillips, R.; Meier, I.; et al. (2012). "Roots and fungi accelerate carbon and nitrogen cycling in forests exposed to elevated CO2". Ecology Letters. 15 (9): 1042–1049. doi:10.1111/j.1461-0248.2012.01827.x. PMID 22776588.
  42. Richert, Catharine (7 October 2009), "PlantsNeedCO2.org claims that carbon dioxide is not a pollutant and is good for the environment", PolitiFact
  43. Hessayon, DG (1992). The Garden DIY Expert. pbi Publications. p. 104. ISBN 978-0-903505-37-6.
  44. La Notte, Luca; Giordano, Lorena; Calabrò, Emanuele; Bedini, Roberto; Colla, Giuseppe; Puglisi, Giovanni; Reale, Andrea (15 November 2020). "Hybrid and organic photovoltaics for greenhouse applications". Applied Energy. 278: 115582. doi:10.1016/j.apenergy.2020.115582. ISSN 0306-2619. S2CID 224863002.
  45. Kempkens, Wolfgang. "Strom aus dem Gewächshaus". Golem.de. Retrieved 18 September 2022.
  46. Carron, Cécilia. "With new solar modules, greenhouses run on their own energy". Ecole Polytechnique Federale de Lausanne via techxplore.com. Retrieved 18 September 2022.
  47. "Shade houses". harnois.com. Archived from the original on 10 June 2016. Retrieved 3 June 2016.
  48. "Home Wicking_boxes Wicking_beds Our_standard_shade_house Macro-pots_and_small_beds Our Standard Shade-house". easygrowvegetables.net. Archived from the original on 2 April 2016.
  49. "La superficie de invernaderos de Andalucía oriental crece hasta las 35.489 hectáreas, un 1,7% más que en la pasada campaña". Consejería de Agricultura, Ganadería, Pesca y Desarrollo Sostenible (in Spanish). Junta de Andalucía. 4 November 2018. Retrieved 16 October 2019.
  50. Kraemer, Susan (30 November 2017). "GlassPoint Belridge Solar Project". solarpaces.org.
  51. Griffith, Anna N. (1985), Collins Guide to Alpines and Rock Garden Plants, London: Collins, pp. 20–21, ISBN 978-0-907486-81-7
  52. McNutty, Jennifer (3 November 2017). "Solar greenhouses generate electricity and grow crops at the same time, UC Santa Cruz study reveals". USC Newscenter. Santa Cruz: University of California. Retrieved 6 November 2017.
  53. Netherlands, Statistics. "Upscaling of greenhouse vegetable production". Statistics Netherlands. Retrieved 10 June 2022.
  54. "gewassen, dieren en grondgebruik naar regio". CBS StatLine – Landbouw. Retrieved 10 July 2016.
  55. "economische omvang naar omvangsklasse, bedrijfstype". CBS StatLine – Landbouw. Retrieved 10 July 2016.
  56. Peters, Adele (13 March 2020). "See the Netherlands' massive network of greenhouses from above". Fastcompany.com. Retrieved 22 June 2021.
  57. "Could high-tech Netherlands-style farming feed the world?". Deutsche Welle. 23 January 2019. Retrieved 22 June 2021.

General and cited references

Further reading

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.