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μSR: Report on the 4th International Conference at Uppsala

Published online by Cambridge University Press:  29 November 2013

Kenneth M. Crowe
Affiliation:
University of California-Berkeley
Alan M. Portis
Affiliation:
Lawrence Berkeley Laboratory
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Extract

“His Majesty the Spin and μSR, the Youngest Princess,”—this was the title of the keynote address of Anatole Abragam, professor in the College de France, who opened the 4th International Conference, μSR, held in Uppsala, Sweden June 23-27, 1986. With more than 100 papers and almost 150 participants, the topics discussed covered the range from the most recent level-crossing resonance (LCR) studies and the quantum diffusion of muons in metals through muons in spin glasses, semiconductors, alkali halides and oxides, to muonium-radical chemistry and reaction pion dynamics as well as channeling and other new techniques.

Although μSR studies began in 1957, the first real advances in the field were not made until the mid 1970s when muon trapping sites in solids were first unambiguously identified. These last ten years have seen materials scientists join with nuclear and particle physicists at the meson facilities: LAMPF at Los Alamos, TRIUMF at Vancouver, CERN at Geneva, SIN at Zurich, and KEK at Tokyo. U.S. federal support of visiting materials science user groups at these facilities has recently been examined by a National Academy of Science Panel.

For the materials scientist, the muon offers a new, light, hydrogen-like probe of great sensitivity with which to investigate internal magnetic fields. This report will examine just a few current problems in order that workers outside the field might catch a glimpse of the present excitement of the subject and obtain a brief introduction to current techniques.

μSR is based on the following sequence of events: pions produced by high-intensity proton accelerators decay to muons, which are highly polarised along their momenta, and to neutrinos.

Type
Technical Features
Copyright
Copyright © Materials Research Society 1986

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References

1.Heffner, R.H., Crowe, K.M., Estle, T.L., Huber, D.L., Kossler, W.J., Lynn, K.C., MacLaughlin, D.E. and Richards, P.M., Muon Sources for Solid-Slate Research, Report of the Subcommittee on Muon Sources for Solid State Research, Solid State Sciences Committee, National Research Council (National Academy Press, Washington, DC 1984).Google Scholar
2.Abragam, A., C.R. Acad. Sci. Ser. 2, 299 (1984) p. 95.Google Scholar
3.Kreitzman, S.R., Brewer, J.H., Harshman, D.R., Keitel, R. and Williams, D. L., Crowe, K.M. and Ansaldo, E.J., Phys. Rev. Lett. 56 (1986) p. 181.CrossRefGoogle Scholar
4.Kreitzman, S.R.,“Muon Level Crossing Resonance in Diamagnetic Systems - General Considerations,“ to appear in μSR-86 proceedings.Google Scholar
5.Kondo, J., Physica 125B (1984) p. 279; 126B (1984) p. 377.Google Scholar
6.Seeger, A. and Schimmele, L., Hyperfine Interactions 17–19 (1984) p. 133138.CrossRefGoogle Scholar
7.Brewer, J.H., Celio, M., Harshman, D.R., Keitel, R., Kreitzman, S.R., Luke, G.M., Noakes, D.R. and Turner, R.E., Ansaldo, E.J., Clawson, C.W., Crowe, K.M., and Huang, C.Y., “Determination of Very Slow μ+ Hop Rates in Cu by LLF-μSR,”to appear in μSR-86 proceedings.Google Scholar
8.Portis, A.M., Crowe, K.M., and Keitel, R., “Search for Muon Drift in Copper,” Physics Letters A 117 (1986) p. 234; K.M. Crowe and A.M. Portis, “Electron Wind-Induced Muon Drift in Metals,” to appear in μSR-86 proceedings.CrossRefGoogle Scholar
9.Kiefl, R.F., Kreitzman, S., Celio, M., Keitel, R., Luke, G.M., Brewer, J.H., Noakes, D.R., Percival, P.W., Matsuzaki, T., and Nishiyama, K., Phys. Rev. A34 (1986) p. 681.CrossRefGoogle Scholar
10.Heffner, R.H., Cooke, D.W., Fisk, Z., Hutson, R.L., Schillaci, M.E., Smith, J.L., Willis, J.O., MacLaughlin, D.E., Boekema, C., Lichti, R.L., Denison, A.B., and Oostens, J., “Muon Knight Shift and Zero-Field Relaxation in (U, TH)Be13,” to appear in μSR-86 proceedings.Google Scholar
11.Odermatt, W. , Baumeler, Hp., Keller, H., Kundig, W., Patterson, B.D., Schneider, J.W., Sellschop, J.P.F., Stemmet, M.C., Connell, S., and Spencer, D.P., “Absolute Sign of the Mu* Hyperfine Parameters in Diamond,” to appear in μSR-86 proceedings.Google Scholar
12.Uemura, Y.J., Keitel, R., Senba, M., Kiefl, R.F., Kreitzman, S.R., Noakes, D.R., Brewer, J.H., Harshman, D.R., Ansaldo, E.J., Crowe, K.M., Portis, A.M., and Jaccarino, V., “μ+SR Studies on Pure MnF2 and Site-Diluted (Mn0.5Sn0.5)F2,” to appear in μSR-86 proceedings.Google Scholar
13.Brewer, J.H., Kreitzman, S.R., Noakes, D.R., Ansaldo, E.J., Harshman, D.R., and Keitel, R., “Observation of Muon-Fluorine ‘Hydrogen Bonding’ in Ionic Crystals,” Phys. Rev. B33 (1986) p. 7813; also to appear in μSR-86 proceedings.CrossRefGoogle Scholar
14. For a recent, comprehensive review of μSR, see the monograph of Alex Schenek of SIN, who provided the conference summary. Schenck, A., Muon Spin Rotation Spectroscopy-Principles and Applications in Solid State Physics, (Adam Hilger Ltd., Bristol and Boston, 1985).Google Scholar