High temperature expansion for the SU(n) Heisenberg model in one dimension

Fukushima, N.; Kuramoto, Y.

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High temperature expansion for the SU(n) Heisenberg model in one dimension

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Fukushima, N.
Max Planck Institute for the Physics of Complex Systems, Max Planck Society;

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Fukushima, N., & Kuramoto, Y. (2002). High temperature expansion for the SU(n) Heisenberg model in one dimension. Journal of the Physical Society of Japan, 71(5), 1238-1241. Retrieved from http://jpsj.ipap.jp/cgi-bin/getarticle?magazine=JPSJ&volume=71&number=5&page=1238-1241.

Zitierlink: https://hdl.handle.net/11858/00-001M-0000-002B-379C-4

Zusammenfassung

Thermodynamic properties of the SU(n) Heisenberg model with the nearest-neighbor interaction in one dimension are studied by means of high-temperature expansion for arbitrary n. The specific heat up to 0[(betaJ)(23)] and the correlation function up to O[(betaJ)(19)] are derived with betaJ being the antiferromagnetic exchange in units of temperature. The series coefficients are obtained as explicit functions of n. It is found for n > 2 that the specific heat exhibits a shoulder on the high-temperature side of a peak. The origin of this structure is clarified by deriving the temperature dependence of the correlation function. With decreasing temperature, the short-range correlation with two-site periodicity develops first, and then another correlation occurs with n-site periodicity at lower temperature. This behavior is in contrast to that of the 1/r(2)-model, where the specific heat shows a single peak according to the exact solution.