Chemical purification of molybdenum samples for the NEMO 3 experiment

• Published in: Nuclear instruments & methods in physics research. Section A, Accelerators, spectrometers, detectors and associated equipment Vol. 474; no. 1; pp. 93 - 100
• Main Authors: Arnold, R., Augier, C., Baker, J., Barabash, A., Bing, O., Blum, D., Brudanin, V., Caffrey, A.J., Campagne, J.E., Caurier, E., Dassie, D., Egorov, V., Errahmane, K., Filipova, T., Guyonnet, J.L., Hubert, F., Hubert, Ph, Jullian, S., Kochetov, O., Kisel, I., Kornoukhov, V.N., Kovalenko, V., Kuzichev, V.F., Lalanne, D., Laplanche, F., Leccia, F., Linck, I., Longuemare, C., Marquet, Ch, Mauger, F., Nicholson, H.W., Nikolic-Audit, I., Pilugin, I., Piquemal, F., Reyss, J-L., Riddle, C.L., Sarazin, X., Scheibling, F., Stekl, I., Suhonen, J., Sutton, C.S., Szklarz, G., Timkin, V., Tretyak, V., Umatov, V., Vanyushin, I., Vorobel, V., Vylov, Ts
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 21.11.2001
• Subjects: Double beta decay; HPGe spectrometry; Molybdenum; NEMO 3; 23.40.−s; Double beta decay; HPGe spectrometry; Molybdenum; NEMO 3

Most currently, viable double beta decay experiments require highly enriched isotopic sources. These sources must be extraordinarily free of radioactive contamination. The double beta decay experiment NEMO 3 will study 100Mo, for which physical and chemical purification techniques have been investig...