The role of plutonium-238 in nuclear fuel cycles

Massey, John Victor

05 1900

No description available.

Plutonium

Reactor fuel reprocessing

The displacement of metals from butylphosphate complexes

Lloyd, C. J.

January 1988

No description available.

628.4

Nuclear fuel reprocessing

Influence of temperature on the extraction of Pu(IV) by tri-n-butyl phosphate from acidic nitrate solutions /

Brown, M. Alex.

January 1900

Thesis (M.S.)--Oregon State University, 2010. / Printout. Includes bibliographical references (leaves 43-45). Also available on the World Wide Web.

Plutonium Reactor fuel reprocessing.

Heavy metal extraction using advanced liquid-liquid style partitioning systems

Tucker, Kate Louise

January 2015

Understanding the behaviour of heavy metals involved in the nuclear fuel cycle is of paramount importance to the reprocessing and storage of spent nuclear fuel. These studies have attempted to obtain a greater understanding of the fundamental chemistry of these systems, by investigating extraction performance and speciation in current (PUREX) and proposed (GANEX) extraction processes. Various complexes have been shown to exist in the post-extracted organic fraction of the systems analysed. For Zr(IV), U(VI) and Np(VI) separated from aqueous nitric and hydrochloric using TBP, the complexes [Zr(NO3/Cl)4(TBP)4], [UO2(NO3/Cl)2(TBP)2] and [NpO2(NO3/Cl)2(TBP)2] formed, respectively. For Zr(IV) separated from aqueous mixtures of HNO3 and HCl at equal concentration, a preference was shown to [Zr(Cl)4(TBP)4] over the analogous nitrate complex. For U(VI) separated from aqueous mixtures of HNO3 and HCl, a preference was shown to [UO2(Cl)2(TBP)2], even at high aqueous nitrate concentrations. NMR data for Pu(IV) separated from aqueous HNO3, HCl and mixtures of both, using TBP were presented, where possible complexation was observed. It is thought that [Pu(NO3)4(TBP)4] or [PuCl4(TBP)4] species existed within the organic fraction for Pu(IV) separated from aqueous HNO3 and HCl, respectively. These systems showed high distribution ratios where an increase was observed with increasing aqueous acid concentration overall. Distribution ratio data were presented for the lanthanide series separated from aqueous nitric acid, using the proposed GANEX solvent system(s). The lanthanides analysed showed an increase in distribution ratio with increasing aqueous nitric acid concentration and with increasing TODGA concentration in the organic fraction. Heavier lanthanides were observed to give higher distribution ratios overall. The best distribution ratios were observed for lanthanides separated using 0.2 M TODGA with 1-octanol (5 % by volume) over the nitric acid concentration range analysed. For lanthanides separated using 0.5 M DMDOHEMA, an optimum distribution ratio was observed at around 6 M aqueous nitric acid concentration. The distribution ratio data for lanthanides separated from a range of DMDOHEMA concentrations, were observed to increase with increasing organic DMDOHEMA concentration. The distribution ratios observed for isotopes of Np, Am, Eu and Pu separated using 0.2 M TODGA, increased with increasing aqueous nitric acid concentration. The same trend was observed for the aforementioned isotopes separated using 0.5 M DMDOHEMA. However, pertechnetate separated using 0.2 M TODGA from aqueous nitric acid, showed a decrease in the distribution ratios observed over the acid concentration range analysed. This was contrary to pertechnetate separated from aqueous nitric acid using 0.5 M DMDOHEMA, where a small increase in distribution ratio was observed over the concentration range analysed. For Np(VI) separated from some proposed GANEX solvents, the 0.2 M TODGA/0.5 DMDOHEMA combination gave the best distribution of neptunium into the organic fraction. For Np(VI) separated using 0.5 M DMDOHEMA, the complex [Np(DMDOHEMA)2(NO3)4] was observed. Additional attempts to analyse Np(VI) behaviour under GANEX style conditions via EXAFS, were not successful due to immediate reduction of the Np(VI) on the beam line.

553.4

Nuclear fuel reprocessing

Extraction of ruthenium species from dilute aqueous streams using modified inorganic materials

Helps, Kevin D.

January 1991

No description available.

541.38

Nuclear fuel reprocessing wastes

The irradiation effects on the solvent extraction system of tributyl phosphate-dodecane

Holland, Joe Paschal

January 2011

Typescript. / Digitized by Kansas Correctional Industries

Reactor fuel reprocessing

Radiation chemistry

Nuclear fuel reprocessing plant radioactive airborne effluents sources and treatment

Roles, Gary William

January 1978

No description available.

Optimization of breeding performance for metallic Pu-Th, U[superscript]233-Th, U[superscript]233-U[superscript]238 and for (Pu-U)0[subscript]2 fuels in LMFBRs

Lee, Chung-Chiang Patrick

12 1900

No description available.

Breeder reactors

Reactor fuel reprocessing

The use of organophosphorus extractants in f-element separations

Braley, Jenifer Claire.

January 2010

Thesis (Ph. D.)--Washington State University, August 2010. / Title from PDF title page (viewed on July 21, 2010). "Department of Chemistry." Includes bibliographical references (p. 217-218).

The chemistry of acetohydroxamic acid related to nuclear fuel reprocessing /

Matteson, Brent Searle.

January 1900

Thesis (Ph. D.)--Oregon State University, 2011. / Printout. Includes bibliographical references (leaves 119-132). Also available on the World Wide Web.