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K. Schwochau

Bio: K. Schwochau is an academic researcher. The author has contributed to research in topics: Uranium & Seawater. The author has an hindex of 4, co-authored 4 publications receiving 355 citations.
Topics: Uranium, Seawater

Papers
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Journal ArticleDOI
TL;DR: In this paper, it was shown that poly(acrylamidoxime) resins are suitable for the accumulation of uranium from natural seawater of pH = 8.1-8.3.
Abstract: Hydroxylamine derivatives of cross-linked poly(acrylonitriles), so-called poly(acrylamidoxime) resins, are suitable for the accumulation of uranium from natural seawater of pH = 8.1–8.3. Depending on the method of manufacture, these sorbers yield excellent uranium loadings up to some thousand ppm which roughly equals the average uranium content of actually explored uranium ores. The rate of uranium uptake, which is 5-30 ppm/d at room temperature, increases with increasing temperature of seawater. Uranium can be eluted by 1 M HCl with an elution efficiency of more than 90%. Owing to a certain instability of the uranium binding groups in acid eluants, the uranium uptake decreases with increasing number of sorption-elution cycles. Hydroxylamine derivatives of poly(acrylonitrile) are shown to contain simultaneously at least two kinds of functional groups: open-chain amidoxime groups which are stable and cyclic imidoxime groups which are unstable in 1 M HCl. Experimental evidence is presented that the...

177 citations

Journal ArticleDOI
TL;DR: In this paper, some essential chemical aspects of a large-scale sorptive recovery of uranium from seawater are discussed with special emphasis on required sorber properties such as high physical and chemical stability in seawater, fast and selective uptake of uranium, as well as a sufficient loading capacity.
Abstract: At an average uranium content of 3.3 ppb the oceans can be considered as a very low-grade but practically unlimited source of uranium. Some essential chemical aspects of a large-scale sorptive recovery of uranium from seawater are discussed with special emphasis on required sorber properties such as high physical and chemical stability in seawater, fast and selective uptake of uranium, as well as a sufficient loading capacity. Systematic screening tests, including about 200 sorber materials on the basis of organic ion-exchange resins, identified cross-linked poly(acrylamidoximes) as the most promising candidate sorbers. Their uranium uptake closely approaches the uranium content of actually explored uranium ores.

174 citations

Journal ArticleDOI
TL;DR: In this paper, the magnetic susceptibilities obey the Curie-Weiss law over the temperature range 77-298°K with μeff=1.63 μB, 1.60 μB and 1.47 μB.
Abstract: [(CH3)4N]2MnO4, [(CH3)4N]2TcO4, and [(CH3)4N]2ReO4 are isotypic and crystallize in an antifluoritelike cubic face centered lattice with a=11.09 A (Mn), 11.20 A (Tc), and 11.35 A (Re). The magnetic susceptibilities obey the Curie–Weiss law over the temperature range 77–298 °K with μeff=1.63 μB (Mn), 1.60 μB (Tc), and 1.47 μB (Re). The magnetic moments of [(CH3)4N]2TcO4 and [(CH3)4N]2ReO4 as well as the splitting and vibrational structure of the 2E→2T2 intrashell transition indicate strong Jahn–Teller distortion of TcO42− and ReO42− in the first excited 2T2 state. Tetrahedral crystal field parameters of Δ=−11 kK, Δ=−17 kK, and Δ=−19 kK are derived for MnO42−, TcO42−, and ReO42−. The electron transfer spectra reflect the lower degree of covalency of the Re–O bond in comparison to the Tc–O and Mn–O bond.

20 citations

Journal ArticleDOI
TL;DR: In this paper, the complex anions [TcIV(NCS)6]2− and [tcV6]6]− are prepared and isolated as [(CH3)4N]-salts.

18 citations


Cited by
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Journal ArticleDOI
TL;DR: This review comprehensively surveys materials developed from 2000-2016 for recovery of seawater uranium, in particular including recent developments in inorganic materials; polymer adsorbents and related research pertaining to amidoxime; and nanostructured materials such as metal-organic frameworks, porous-organic polymers, and mesoporous carbons.
Abstract: More than 1000× uranium exists in the oceans than exists in terrestrial ores. With nuclear power generation expected to increase over the coming decades, access to this unconventional reserve is a matter of energy security. With origins in the mid-1950s, materials have been developed for the selective recovery of seawater uranium for more than six decades, with a renewed interest in particular since 2010. This review comprehensively surveys materials developed from 2000–2016 for recovery of seawater uranium, in particular including recent developments in inorganic materials; polymer adsorbents and related research pertaining to amidoxime; and nanostructured materials such as metal–organic frameworks, porous-organic polymers, and mesoporous carbons. Challenges of performing reliable and reproducible uranium adsorption studies are also discussed, as well as the standardization of parameters necessary to ensure valid comparisons between different adsorbents.

566 citations

Journal Article
TL;DR: In this article, a theory of the band strength based on the point-charge model and p-d mixing has been developed and applied to the data with results in fair agreement with experiment.
Abstract: The polarized optical spectra of the ions Ti3+, V3+, Cr3+, Mn3+, Co3+, and Ni3+ in corundum single crystals have been studied at temperatures from 4.2° to 1200°K. A theory of the band strength based on the point‐charge model and p‐d mixing has been developed and applied to the data with results in fair agreement with experiment. The effects of temperature show that the vibrational‐electronic contribution to band strength is quite small at low temperature but may be appreciable at high temperatures. The crystal‐field parameters have been calculated as convergent lattice sums. The observed trigonal‐field parameter has the opposite sign from that calculated by the point‐charge model if the impurity ion is assumed to occupy an Al3+ ion position in the lattice, but has the same sign as calculated for an ion 0.1 A displaced along the c3 axis toward the empty octahedral site. Details of the spectra have been interpreted as showing that the surroundings of an ion are distorted in some electronic states.

543 citations

Journal ArticleDOI
01 May 1990-Talanta
TL;DR: This review is concerned mainly with the applications of chelating polymeric resins for the separation and concentration of trace metals from oceans, rivers, streams and other natural systems.

409 citations

Journal ArticleDOI
TL;DR: Uranium adsorption from seawater has been investigated for over six decades in efforts to secure uranium sources for future energy production as discussed by the authors, with the majority of the research activities focused on inorganic materials, chelating polymers, and nanomaterials.
Abstract: The recovery of uranium (U) from seawater has been investigated for over six decades in efforts to secure uranium sources for future energy production. The majority of the research activities have focused on inorganic materials, chelating polymers, and nanomaterials. Previous studies of uranium adsorption from aqueous solutions, mainly seawater, are reviewed here with a focus on various adsorbent materials, adsorption parameters, adsorption characterization, and marine studies. Continuous progress has been made over several decades, with adsorbent loadings approaching 3.2 mg U/g adsorbent in equilibrium with seawater. Further research is needed to improve first, the viability including improved capacity, selectivity, and kinetics, and second, the sorbent regeneration for multicycle use. An overview of the status of the uranium adsorption technology is provided and future research needs to make this technology commercially competitive are discussed.

383 citations

Journal ArticleDOI
TL;DR: In this paper, a half-wave rectified alternating current electrochemical (HW-ACE) method was used for uranium extraction from sea water based on an amidoxime-functionalized carbon electrode.
Abstract: In total there is hundreds of times more uranium in sea water than on land, but extracting it for use in nuclear power generation is challenging due to its low concentration (∼3 ppb) and the high salinity background. Current approaches based on sorbent materials are limited due to their surface-based physicochemical adsorption nature. Here we use a half-wave rectified alternating current electrochemical (HW-ACE) method for uranium extraction from sea water based on an amidoxime-functionalized carbon electrode. The amidoxime functionalization enables surface specific binding to uranyl ions, while the electric field can migrate the ions to the electrode and induce electrodeposition of uranium compounds, forming charge-neutral species. Extraction is not limited by the electrode surface area, and the alternating manner of the applied voltage prevents unwanted cations from blocking the active sites and avoids water splitting. The HW-ACE method achieved a ninefold higher uranium extraction capacity (1,932 mg g−1) without saturation and fourfold faster kinetics than conventional physicochemical methods using uranium-spiked sea water. The large amount of uranium in the oceans could be exploited for nuclear fuel, but existing physicochemical extraction methods are limited in terms of capacity and rates of removal. Here the authors use an electrochemical extraction technique, demonstrating improved uptake capacity and kinetics.

338 citations