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The Efficiency of Arsenic Acid in Cotton Desiccation

Published online by Cambridge University Press:  12 June 2017

Charles S. Miller
Charles S. Miller*
Affiliation:
Dep. of Plant Sci., Texas A&M Univ., College Station, TX 77843
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Abstract

The application of individual droplets of an aqueous solution of As-74-labeled arsenic acid to the leaves, petioles, green stems and stalks of greenhouse-grown cotton plants (Gossypium hirsutum L. cv ‘Deltapine’) enabled the estimation of 100 ppm of As as the minimum effective internal concentration (MEIC) of arsenic from arsenic acid needed for the desiccation of cotton leaves. The spray application of arsenic acid to cotton plants (cv Lankart) in the field was calculated to have an overall efficiency of below 5 percent for this particular spraying operation. The application of aqueous arsenic acid to the abraded stalks of greenhouse-grown cotton plants (cv G-272) resulted in translocation of approximately 87% of the recovered arsenic so that treatment half-way around the stalk produced 70% desiccation. Treatment with sufficient quantities around the entire stalk resulted, in most cases, in complete desiccation and prevention of regrowth.

Type
Research Article
Information
Weed Science , Volume 22 , Issue 4 , July 1974 , pp. 388 - 393
Copyright
Copyright © 1974 by the Weed Science Society of America 

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References

Literature Cited

1. Aboul-Ela, M.M. and Miller, C.S. 1965. Studies of Arsenic Acid Residues in Cotton. Tex. Agr. Exp. Sta. MP 771.Google Scholar
2. Bliss, C.I. 1952. The Statistics of Bioassay. Vol. 2 Academic Press, Inc. 183 pp.Google Scholar
3. Cook, E.D. 1956. Cotton Defoliation in the Blackland Area. Proc. 11th Ann. Cotton Defol. Physiol. Conf. pp. 2223.Google Scholar
4. Davis, F.S., Villarreal, A., Baur, J.R., and Goldstein, I.S. 1972. Herbicidal Concentrations of Picloram in Cell Culture. Weed Sci. 20:185189.Google Scholar
5. Finney, D.J. 1952. Probit Analysis 2nd edit., Cambridge University Press. 333 pp.Google Scholar
6. Hall, W.C., Cook, E.D., Thaxton, E.L., Burleson, C.A., Tippit, O.J., and Johnson, S.P. 1957. Cotton Harvest-Aid Chemical Tests in Texas, 1956. Tex. Agr. Exp. Sta. PR 1935.Google Scholar
7. Miller, C.S., Cook, E.D., Hubbard, J.L., Newman, J.S., Thaxton, E.L., and Wilkes, L.H. 1968. Cotton Desiccation Practices and Experimental Results in Texas. Tex. Agr. Exp. Sta. MP 903.Google Scholar
8. Miller, C.S. and Endrizzi, J.E. 1962. Preliminary Studies on the Physiology and Genetics of a Defoliant Resistant Cotton. Proc. Cotton Defoliation-Physiology Conf. pp. 3034.Google Scholar