Leason Adams

Leason Heberling Adams (January 16, 1887 August 20, 1969) was an American geophysicist and researcher. His principal achievement was his research on the properties of materials exposed to very high pressures, which he used to derive information on the nature of the Earth's interior. He received the William Bowie Medal of the American Geophysical Union in 1950 for his work.[2][3]

Leason Heberling Adams
Born(1887-01-16)January 16, 1887
DiedAugust 20, 1969(1969-08-20) (aged 82)
NationalityAmerican
Alma materUniversity of Illinois (B.S., 1906)[1]
Tufts University (Sc.D., 1941)[1]
Scientific career
InstitutionsCarnegie Institution (1910 - 1952)[1]

Biography

Born on 16 January 1887, Adams grew up in central Illinois, where he received his early education in a one-room school. At the age of fifteen he entered the University of Illinois at Urbana–Champaign, graduating in 1906 with a Bachelor of Science degree in chemical engineering.

After completing his university studies, he worked for the Technology Branch of the United States Geological Survey, first as an industrial chemist and then as a physical chemist. In 1910 he began working at the Geophysical Laboratory of the Carnegie Institution for Science in Washington, D.C. In 1937 he became the director of the Laboratory, and during World War II he served as the director of Division I (ballistics) of the Office of Scientific Research and Development. He was elected to the United States National Academy of Sciences in 1943.

Adams retired from the Carnegie Institution in 1952 but continued to carry out research, first as a consultant to the director of the National Bureau of Standards and then from 1958 until 1965 as a professor of geophysics at the University of California, Los Angeles.

He died on 20 August 1969 in Silver Spring, Maryland.[4]

Research

Adams performed one of his first research projects during World War I, when he produced optical glass. He helped to develop a new method for annealing glass which was effective for large blocks, and then used this technique to make a 200-inch mirror for the Hale telescope at the Mount Palomar Observatory. For this work, he received the Edward Longstreth Medal of the Franklin Institute.

Geophysical work

His most enduring work began in 1919, when he was working at the Carnegie Institution for Science to develop new methods for high-pressure measurement. In the late 19th century the prevailing view of the Earth was that it was made up of a thin crust floating on a molten interior. By Adams' day, this view was being challenged, especially by the findings of some seismologists who had found the wave velocities of the Earth at different depths. Wave velocities depend upon the elastic constants of the materials through which they pass, in particular the bulk modulus and stiffness.

It should be possible to combine the experimentally-determined wave velocities of the various parts of the Earth's interior and the elasticity data from various rocks in order to find out about the Earth's interior. However, by the early 20th century no one had been able to determine the elastic constants of common rocks, because almost all rocks are slightly porous, complicating conventional elasticity measurement methods.

Adams was able to solve this problem by fashioning rocks into cylinders, putting thin hermetically sealed metal jackets around them, and subjecting them to high pressures while inside a mobile liquid in a pressure vessel. By recording the piston displacement required in order to achieve a given pressure, Adams could find the volume change of the rocks and their bulk modulus.

Implications

These experiments had important implications for the field of geophysics. Adams used the measured bulk modulus of various rocks to find their wave velocities and then compared his results with the wave velocities of the Earth, which had been determined through seismology. He concluded that the high central density required for the known density of the Earth could not be accounted for by the compression of ordinary silicate minerals; the inner core of the Earth must be composed of a heavy iron-nickel material.

In addition, research performed by the Croatian seismologist Andrija Mohorovičić indicated that there exists a region of the Earth's interior, the Mohorovičić discontinuity, where high wave velocities coincide with shallow depths. Adams' work showed that only two minerals, dunite and eclogite, could possible make up the discontinuity, and further exploration showed that dunite was a better fit than eclogite.

Therefore, by combining his own elasticity calculations with current seismographic research, Adams was able to show that the conventional view of the Earth's interior as a uniform molten liquid was false, and that the Earth is in fact composed of a nickel-iron core, a thin crust, and that aside from a thin layer of dunitic material between the Earth's crust and mantle, the rest of the Earth's interior is iron, magnesium, silicon, and oxygen.

Awards and honors

References

  1. "Leason H. Adams". Geophysical Laboratory, Carnegie Institution of Washington. 2005. Archived from the original on 26 March 2019.
  2. Jay E. Greene, ed. (1966). McGraw-Hill Modern Men of Science. McGraw-Hill. pp. 3–4.
  3. Gibson, pp.1-33
  4. Leason Heberling Adams papers, p.3, Biographical Note
  5. Gibson, p.17
  6. "Presidents of the Philosophical Society of Washington". Philosophical Society of Washington. Archived from the original on July 4, 2008. Retrieved November 13, 2011.
  7. "Franklin Laureate Database - Edward Longstreth Medal 1921 Laureates". Franklin Institute. Retrieved November 13, 2011.
  8. Gibson, p.6
  9. "Search Deceased Member Data". U.S. National Academy of Sciences. Retrieved November 13, 2011.
  10. "National Academy of Sciences". Proceedings of the National Academy of Sciences, USA. 42 (7): 445–480. 1956. doi:10.1073/pnas.42.7.445. PMC 534248. PMID 16589888. On page 445, the entry Adams, Leason Heberling indicates election year 1943 for NAS Section (13) Geophysics.
  11. Gibson, p.9
  12. "William Bowie Medal, Past Recipients". American Geophysical Union. Retrieved November 13, 2011.

Bibliography

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