J1-J2 Quantum Heisenberg Antiferromagnet: Improved Spin-Wave Theories Versus Exact-Diagonalization Data

Abstract

We reconsider the results cocerning the extreme-quantum S=1/2 square-lattice Heisenberg antiferromagnet with frustrating diagonal couplings (J1-J2 model) drawn from a comparison with exact-diagonalization data. A combined approach using also some intrinsic features of the self-consistent spin-wave theory leads to the conclusion that the theory strongly overestimates the stabilizing role of quantum flutcuations in respect to the N\'eel phase in the extreme-quantum case S=1/2. On the other hand, the analysis implies that the N\'eel phase remains stable at least up to the limit J2/J1 = 0.49 which is pretty larger than some previous estimates. In addition, it is argued that the spin-wave ansatz predicts the existence of a finite range (J2/J1<0.323 in the linear spin-wave theory) where the Marshall-Peierls sigh rule survives the frustrations.

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