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Arthur Wallace

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Arthur Wallace
BornArthur Wallace
(1919-01-04)January 4, 1919
Bear River City, Utah
DiedOctober 11, 2008(2008-10-11) (aged 89)
Santa Monica, California
OccupationProfessor of Plant Physiology at UCLA; Wallace Laboratories
NationalityAmerican

Arthur Wallace (January 4, 1919 in Bear River City, Utah – October 11, 2008 in Santa Monica, California), was a soil scientist.

Biography

Schooling

Wallace received a B.S. from Utah State University (chemistry) in 1943 and at Ph.D. from Rutgers University in 1949 (soils and plant nutrition).

Professor

He was a professor of Plant Physiology at University of California, Los Angeles (1949–1989).

Accomplishments

Wallace was elected Fellow of the American Society of Agronomy, of the Soil Science Society of American, of the Crop Science Society of America, and of the American Society for Horticultural Science.

Work & Publications

Dr. Iron

Wallace was known as “Dr. Iron”[who?] for his research and studies on chelated iron. At a meeting in Berkeley, California held on December 11, 1953, he formulated the structure of EDDHA which was synthesized by his friend, Harry Kroll and which was commercialized by Geigy as Fe-EDDHA and Sequestrene 138. At that time, EDTA, HEEDTA and DTPA were known. Fe-EDTA was effective in the acidic Florida soils but failed in California giving chelates a poor reputation later reversed with the astounding success of Fe-EDDHA.

He helped organize the biannual international iron nutrition and interactions symposia[1] which have been held since 1979. Wallace hosted the first one at UCLA.

Working in the Middle East and Africa

He worked with plant mineral nutrition problems in the Middle East and Africa. He made 30 visits to Egypt working with Yossef Wiley, minister of agriculture, to solve some of their agricultural production problems.

Law of the Maximum

Wallace is known for his Law of the Maximum in lieu of Liebig's law of the minimum. The Law of the Maximum predicts plant yield based on the additivity of nutrients, growth factors and stress factors. He formulated 13 sound rules for the use of fertilizers.[2]

P.A.M. / Soil Conditioner

Wallace is responsible for the current implementation and success of the soil conditioner – linear, water-soluble, anionic polyacrylamide. Monsanto launched the technology of synthetic and natural polyelectrolytes as soil conditions for the formation of water-stable soil aggregates in 1952.[3] The introduction was written by Firman E. Bear, Arthur’s major professor at Rutgers. The product was marketed under the trade name “Krilium.” The product technically successful but commercially failed due to the high cost of manufacturing and difficulty of use. Krilium became an example of a scientifically successful product but an economical failure. The technology became an embarrassment with an aversion and hesitance to resolve the causes of failure. Dr. Wallace resolved the technical problems, answering the Krilium problem.[4] PAM was reported to be an economic solution of Krilium to condition soil, to reduce soil erosion, to prevent crusting, to help ameliorate sodic soils and to increase crop yield. Various cries were heard such as – “Do not forget the Krilium failure.” PAM is currently fully accepted as a BMP and is used for erosion control such as in burned areas and an economical agricultural soil conditioner.

References

  1. ^ http://www.isinip2010.hu/scientific-program.html
  2. ^ Arthur Wallace (1994). "Generalized environmentally sound rules for use of fertilizers". Communications in Soil Science and Plant Analysis. 25 (1 & 2): 77–86. doi:10.1080/00103629409369009.
  3. ^ BEAR, FIRMAN E. (June 1952). "Synthetic Soil Conditioners". Soil Science. 73 (6): 419.
  4. ^ WALLACE, ARTHUR; WALLACE, GARN A. (May 1986). "Control of Soil Erosion By Polymeric Soil Conditioners". Soil Science. 141 (5): 363–367.{{cite journal}}: CS1 maint: multiple names: authors list (link)

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