Electron-spin resonance was studied in the ${\mathrm{Cr}}_{21}$${\mathrm{Ni}}_{16}$${\mathrm{Mn}}_7$ and ${\mathrm{Cr}}_{20}$${\mathrm{Ni}}_{16}$${\mathrm{Mn}}_6$ austenites with different content of nitrogen and carbon. Measurements were made in the temperature region 10–300 K. Temperature dependences were obtained for the absorption-derivative signal parameters such as the intensity I(T), the width ΔH(T), and the asymmetry parameter R(T). Theoretical analysis of the signal shape revealed that its temperature dependence is equivalent to its dependence on the inverse length of electron diffusion ${\mathrm{\delta }}_{\mathit{e}}$ through the skin layer δ, if the value (δ${\mathrm{\delta }}_{\mathit{e}}$) is constant while the temperature changes. The dependence of the electron-state density on the Fermi surface D(${\mathrm{\varepsilon }}_{\mathit{F}}$) upon the solutes content is deduced from the fitting of theoretical and experimental curves I(T), ΔH(T), and R(T). It was established that D(${\mathrm{\varepsilon }}_{\mathit{F}}$) increases in nitrogen austenite and decreases in carbon austenite with the growth of nitrogen and carbon concentration.

• Received 14 December 1992

DOI:https://doi.org/10.1103/PhysRevB.48.3224