The crystal structure of manganese dioxide

Ormsby, Walter Blackstone

January 1930

No description available.

Manganese.

The reduction of manganese in reservoirs by the gaseous by-products of anaerobic bacterial activity

Wiedeman, John Herman

12 1900

No description available.

Manganese

Manganese content of animal manures and crop residues

Allen, Seward Ellery,

January 1947

Thesis (M.S.)--University of Wisconsin--Madison, 1947. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes Bibliographical references (leaves 40-41).

Manganese.

The determination of manganese by various gravimetric methods ...

Brown, Glenn Vinton.

January 1910

Thesis (Ph. D.)--University of Pennsylvania.

Manganese.

The determination of manganese by various gravimetric methods ...

Brown, Glenn Vinton.

January 1910

Thesis (PH. D.)--University of Pennsylvania.

Manganese.

The electrolytic determination of manganese and its separation from zinc and iron ...

Scholl, George Philipp.

January 1903

Thesis (Ph. D.)--University of Pennsylvania.

Manganese.

Pole-effects, pressure-shifts, and measurements of wave-length in the spectrum of manganese ...

Monk, George Spencer,

January 1923

Thesis (Ph. D.)--University of Chicago, 1923.

Manganese

An electron paramagnetic resonance study of a manganese (IV) ion in a trigonal environment

Byfleet, Colin Russell

January 1969

An electron spin resonance study has been carried out at room temperature, on a magnetically dilute single crystal of ammonium 9-molybdomanganate. A general method for fitting E.S.R. results to a spin Hamiltonian has been devised, and the results of the above study have been used as an example of this method. The values of the parameters thus determined were⃒D⃒= 0.861 ± 0.001 cm⁻¹; g〟 = 1.9920 ± 0.0004 cm⁻¹; g⊥± = 1.9880 ± 0.0004 cm⁻¹;⃒A〟⃒= 0.00760 ± 0.00004 cm⁻¹;⃒A⊥⃒= 0.00684 ± 0.00004 cm⁻¹1. A review of previous theoretical calculations on d³ has been given, and a ligand field approach has been taken in an attempt to interpret the observed parameters. This was successful for the zero field splitting and hyperfine coupling constants, but not for the g-values. The experimental results from a study of an irradiated, single crystal of deuterated ammonium paramolybdate tetrahydrate have also been fitted to a suitable spin Hamiltonian. The principal axes of the g and A tensors were found not to be coincident, and a method for treating the experimental results in this situation has been given. This study showed that the doublet splitting observed earlier, in the E.S.R. spectrum of the irradiated, undeuterated compound, was most probably due to a captured proton. An interpretation of the observed g-values and hyperfine coupling constants has been given, using a molecular orbital approach. / Science, Faculty of / Chemistry, Department of / Graduate

Manganese

Synthesis and studies of n-base appended manganese corroles /

Ng, Nga Chun.

January 2003

Thesis (M. Phil.)--Hong Kong University of Science and Technology, 2003. / Also available in electronic version. Access restricted to campus users.

Manganese oxides. Manganese compounds.

Manganese Oxidation In A Natural Marine Environment- San Antonio Bay

Neyin, Rosemary Ogheneochuko

03 October 2013

In the modern ocean, manganese is oxidized over a timescale of days. To better understand the mechanisms and driving factors for manganese oxidation in the natural environment, experiments were performed with surface water samples collected from the San Antonio Bay. In this study area, the formaldoxime assay was utilized to determine that manganese oxidation is catalyzed via multiple pathways utilizing various catalysts and proximal oxidants. The contribution of catalysts such as colloidal matter, microorganisms and the proximal oxidant superoxide were investigated in the San Antonio Bay. The study suggests that superoxide contributed about 30% of Mn oxidation. The microorganisms and colloids were equal in terms of catalysis and accounted for approximately 100% of Mn oxidation. This study is important because gaining more understanding on the mechanisms by which Mn is oxidized will contribute to its use as a geochemical redox indicator.

Manganese

manganese oxidation

microcosm