Electron Spin Resonance of Copper Manganese Dilute Alloys
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概要
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Electron spin resonance study has been carried out on dilute copper manganese alloys over a temperature range from 1.8°K to 300°K. The relaxation rate is found to increase linearly with temperature over the temperature range where the susceptibility obeys Curie-Weiss' law. The temperature gradient of the relaxation rate has a concentration independent value of 0.96×10^8(sec.^<-1>, deg.^<-1>) for samples with manganese concentration between 0.03 and 0.3 atomic percent in the temperature range below 20°K. Above 0.3 atomic percent, it decreases to a value of 0.34×10^8(sec.^<-1>, deg.^<-1>) for the sample with 5.2 atomic percent manganese. The g-value of the localized spin is 2.010±0.005. It is shown that the experimental results for low concentration samples are well understood in terms of s-d interaction model. According to this model, observed relaxation rate should depend sensitively on the relaxation rate of conduction electron spins as observed, and this relaxation rate was determined as 4.6×10^<13>c(sec.^<-1>) where c is the manganese concentration.
- 社団法人日本物理学会の論文
- 1969-01-05
著者
-
Kinoshita Nobumori
Physics Division Electrotechnical Laboratory
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NAKAMURA Akira
Physics Section, Electrotechnical Laboratory
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Nakamura Akira
Physics Division Electrotechnical Laboratory
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