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Maienschein, J.L.; Magnotta, F.; Herman, I.P.; Aldridge, F.T.; Hsiao, P.
Lawrence Livermore National Lab., CA (USA)1983
Lawrence Livermore National Lab., CA (USA)1983
AbstractAbstract
[en] Isotope separation by means of infrared-laser multiple-photon dissociation offers an efficient way to recover tritium from contaminated light or heavy water found in fission and fusion reactors. For tritium recovery from heavy water, chemical exchange of tritium into deuterated chloroform is followed by selective laser dissociation of tritiated chloroform and removal of the tritiated photoproduct, TCl. The single-step separation factor is at least 2700 and is probably greater than 5000. Here we present a description of the tritium recovery process, along with recent accomplishments in photochemical studies and engineering analysis of a recovery system
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Source
1983; 7 p; 5. topical meeting on technology of fusion energy; Knoxville, TN (USA); 26-28 Apr 1983; CONF-830406--5; Available from NTIS, PC A02/MF A01 as DE83009325
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Report
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Conference
Report Number
Country of publication
BETA DECAY RADIOISOTOPES, BETA-MINUS DECAY RADIOISOTOPES, CHEMICAL REACTIONS, DECOMPOSITION, DIAGRAMS, ELECTROMAGNETIC RADIATION, HYDROGEN COMPOUNDS, HYDROGEN ISOTOPES, INFORMATION, ISOTOPE SEPARATION, ISOTOPES, LIGHT NUCLEI, NUCLEI, ODD-EVEN NUCLEI, ORGANIC CHLORINE COMPOUNDS, ORGANIC COMPOUNDS, ORGANIC HALOGEN COMPOUNDS, OXYGEN COMPOUNDS, RADIATIONS, RADIOISOTOPES, SEPARATION PROCESSES, WATER, YEARS LIVING RADIOISOTOPES
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