A simple way to avoid metastable configurations in the density-matrix renormalization-group algorithms

We investigate the N -leg spin-S Heisenberg ladders by using the density matrix renormalization group method. We present estimates of the spin gap s and of the ground-state energy per site e N ∞ in the thermodynamic limit for ladders with widths up to six legs and spin S 5 2 . We also estimate the ground-state energy per site e 2D ∞ for the infinite two-dimensional spin-S Heisenberg model. Our results support that for ladders with semi-integer spins the spin excitation is gapless for N odd and gapped for N even, whereas for integer spin ladders the spin gap is nonzero, independent of the number of legs. Those results agree with the well-known conjectures of Haldane and Sénéchal-Sierra for chains and ladders, respectively. We also observe edge states for ladders with N odd, similar to what happens in spin chains.

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“…In order to avoid metastable configurations we start the truncation process with large values of m (typically we start with m 0 ∼ 1200) [36].…”

Section: Introductionmentioning

confidence: 99%

N-leg spin-SHeisenberg ladders: A density-matrix renormalization group study

Ramos

Xavier

2014

Phys. Rev. B

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“…In order to avoid metastable configurations we start the truncation process with large values of m (typically we start with m 0 ∼ 1200). 36 In the next section we present our results for the spin-S N -leg Heisenberg ladders: estimates of the ground state energy per site (e N ∞ ) as well the estimates of the spin gap (∆ s ) in the thermodynamic limit. We also show estimates of the ground state energy per site of the twodimensional spin-S Heisenberg model.…”

Section: Ref 27mentioning

confidence: 99%

The N-Leg spin-S Heisenberg ladders: A DMRG study

Ramos,

Xavier

2013

Preprint

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We investigate the N -leg spin-S Heisenberg ladders by using the density matrix renormalization group method. We present estimates of the spin gap ∆s and of the ground state energy per site e N ∞ in the thermodynamic limit for ladders with widths up to six legs and spin S ≤ 5 2 . We also estimate the ground state energy per site e 2D∞ for the infinite two-dimensional spin-S Heisenberg model. Our results support that for ladders with semi-integer spins the spin excitation is gapless for N odd and gapped for N even. Whereas for integer spin ladders the spin gap is nonzero, independent of the number of legs. Those results agree with the well known conjectures of Haldane and Sénéchal-Sierra for chains and ladders, respectively. We also observe edge states for ladders with N odd, similar to what happens in spin chains.

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“…O peso descartado nas varreduras finais foi tipicamente 10-8 -10-12. Para evitar configurações metaestáveis, iniciamos o processo de truncamento com valores grandes de m (tipicamente iniciamos com mo ~ 1200) [127].…”

Section: Com a Decomposição Deunclassified

“…É importante ressaltar que consideramos aqui que uma iteração é composta pelo conjunto da primeira e da segunda parte da varredura. O número de estados retidos é aumentado progressivamente a cada iteração,11 veja por exemplo a referência [127]. A seguir apresentaremos um algoritmo do DMRG para sistema finito.…”

Section: A2 Algoritmo Finitounclassified

Propriedades estáticas e dinâmicas de sistemas fortemente correlacionados

Ramos¹

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In this work, we investigated static and dynamical properties of quasi-one-dimensional strongly correlated systems. The main technique used in the study of such systems was the density matrix renormalization group. In this context, one of the systems that we considered were the spins N-leg Heisenberg ladders. For these ladders, we investigated static proper ties, such as the energy per site in the thermodynamic limit and the spin gap. In particular, we checked the validity of the Haldane-Sénéchal-Sierra's conjecture for the spin gap behavior of the Heisenberg ladders. Also for systems with ladders geometry, another problem that we analyzed was the entanglement entropy of quantum critical ladders. In this case, we proposed a conjecture for the scaling behavior of this entropy. In order to check our conjecture, we con sider free fermions, Heisenberg ladders and quantum Ising ladders. Finally, we investigated the behavior of the dynamical correlations in one-dimensional strongly correlated systems. For this case, we presented a detailed study of the asymptotic behavior of the dynamical spin autocorrelations at the bulk and the boundary of such systems.

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A simple way to avoid metastable configurations in the density-matrix renormalization-group algorithms

Cited by 4 publications

References 19 publications

N-leg spin-SHeisenberg ladders: A density-matrix renormalization group study

N-leg spin-SHeisenberg ladders: A density-matrix renormalization group study

The N-Leg spin-S Heisenberg ladders: A DMRG study

Propriedades estáticas e dinâmicas de sistemas fortemente correlacionados

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