Isotopic exchange and complexation of iron, zinc, and manganese in a long-term marine phytoplankton culture

Riedel, Gerhardt Frederick

03 August 1977

Graduation date: 1978

Plants, Effect of trace elements on

Varietal response and effects of different sources of zinc on soybean growth and yield

Bello, Adetunji B

January 2011

Typescript. / Digitized by Kansas Correctional Industries

Soybean--Fertilizers

Plants--Effect of trace elements on

Zinc

Investigation of Zn-bound proteins in alfalfa using ZN??

Reynolds, Warren Dudley.

January 1957

Call number: LD2668 .T4 1957 R46 / Master of Science

Zinc.

Plants--Effect of trace elements on.

Masters theses

The effect of some micronutrients on the resistance of highland bentgrass to fall armyworms

Watson, Stephen Lawrence

January 2011

Digitized by Kansas Correctional Industries

Plants--Disease and pest resistance

Plants--Effect of trace elements on

Fall armyworm

A STUDY OF CERTAIN ASPECTS OF MICRONUTRIENT ABSORPTION BY PLANTS

Mohamed, Mohamed Fathy Ghoneim, 1936-

January 1966

No description available.

Trace elements in plant nutrition.

Plants -- Effect of trace elements on.

Plants -- Assimilation.

Effect of applied B, Cu, Mn and Zn on soybean yield and micronutrient concentration

Gunaratne, Lionel

January 1984

The effect of applied B, Cu, Mn and Zn on soybean seed yield and tissue micronutrient concentration was studied under different field conditions. Manganese application increased soybean seed yield on the Dragston, Myatt and Slagle fine sandy loams, but not on Rains fine sandy loam. Seed yield was not affected by applied B, Cu or Zn. Broadcast and foliar Mn applications were similarly effective in correction of Mn deficiency and, among foliar Mn applications, split application resulted a higher seed yield than single applications. Micronutrient concentration of the leaf blades, petioles and seeds was increased with the application of B, Cu, Mn and Zn. The increase in tissue B concentration was much greater than that of the other micronutrients. Broadcast Mn application resulted in a higher tissue Mn concentration than foliar Mn applications. The critical Mn concentration in leaf blades at the R1 growth stage was above the level of 13 µg/g, which is reported in the literature. It was concluded that the present calibration of the dilute HC1-H₂SO₄ extractable Mn soil test overpredicts the incidence of Mn deficiency in soybeans. / Master of Science

LD5655.V855 1984.G862

Soybean -- Fertilizers

Plants -- Effect of trace elements on

Boron tolerance in grain legumes with particular reference to the genetics of boron tolerance in peas / Abdolreza Bagheri Kazemabad.

Bagheri Kazemabad, Abdolreza

January 1994

Bibliography: leaves 200-223. / xii, 225, [15] leaves, [19] leaves of plates : ill. (some col.), maps (some col.) ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Plant Science, 1995?

Legumes South Australia.

Peas South Australia.

Plants, Effect of trace elements on.

Soils South Australia Boron content.

Boron tolerance in grain legumes with particular reference to the genetics of boron tolerance in peas

Bagheri Kazemabad, Abdolreza.

January 1994

Bibliography: leaves 200-223.

Legumes South Australia

Peas South Australia

Plants, Effect of trace elements on

Soils South Australia Boron content

Genetic studies on the tolerance of wheat to high concentrations of boron

Yodsaporn Chantachume.

January 1995

Bibliography: leaves 213-245. Genetic control of tolerance to boron was investigated between a moderately tolerant variety, Halberd, a tolerant line G61450 and the moderately sensitive varieties Schomburgk and Condor.

Wheat Varieties Genetics

Plants, Effect of trace elements on

Soils Australia Boron content

Wheat Australia Genetics

Genetics of boron tolerance in durum wheat

Jamjod, Sansanee.

January 1996

Bibliography: leaves 234-256. Genetic studies of tolerance of durum wheat (Triticum turgidum L. var durum) to high concentrations of boron (B) were undertaken to identify genetic variation in response to B, the mode of gene action, number of genes and chromosomal locations of genes controlling tolerance. Results demonstrated that tolerance to B is under simple genetic control as observed in bread wheat. High levels of tolerance can be transferred into sensitive commercial varieties via backcrossing and selection can be performed during seedling growth at early generations.

Wheat Genetics

Boron Physiological effect

Boron Toxicology

Plants, Effect of trace elements on