No enhancement of the localization length for two interacting particles in a random potential

Römer, R. A., Schreiber, M.

30 October 1998

We study two interacting particles in a random potential chain by means of the transfer matrix method. The dependence of the two-particle localization length lampta_2 on disorder and interaction strength is investigated. Our results demonstrate that the recently proposed enhancement of lampta_2 as compared to the results for single particles is entirely due to the finite size of the systems considered. This is shown for a Hubbard-like onsite interaction and also a long-range interaction.

potential chain

Hubbard

MSC 60K40

ddc:530

The Mott-Anderson transition in the disordered one-dimensional Hubbard model

Pai, R. V., Punnoose, A., Römer, R. A.

30 October 1998

We use the density matrix renormalization group to study the quantum transitions that occur in the half-filled one-dimensional fermionic Hubbard model with onsite potential disorder. We find a transition from the gapped Mott phase with algebraic spin correlations to a gapless spin-disordered phase beyond a critical strength of the disorder 1 c ss U= 2. Both the transitions in the charge and spin sectors are shown to be coincident. We also establish the finite-size corrections to the charge gap and the spin-spin correlation length in the presence of disorder and using a finite-size-scaling analysis we obtain the zero temperature phase diagram of the various quantum phase transitions that occur in the disorder-interaction plane.

matrix renormalization

Hubbard

MSC 60K40

ddc:530

The two-dimensional Anderson model of localization with random hopping

Eilmes, A., Römer, R. A., Schreiber, M.

30 October 1998

We examine the localization properties of the 2D Anderson Hamiltonian with off-diagonal disorder. Investigating the behavior of the participation numbers of eigenstates as well as studying their multifractal properties, we find states in the center of the band which show critical behavior up to the system size N=200x200 considered. This result is confirmed by an independent analysis of the localization lengths in quasi-1D strips with the help of the transfermatrix method. Adding a very small additional onsite potential disorder, the critical states become localized.

Hamiltonian

Anderson

eigenstates

multifractal

MSC 60K40

ddc:530

Weak delocalization due to long-range interaction for two electrons in a random potential chain

Römer, R. A., Schreiber, M.

30 October 1998

We study two interacting particles in a random potential chain by a transfer matrix method which allows a correct handling of the symmetry of the two- particle wave function, but introduces an artificial ¨bag¨ interaction. The dependence of the two-particle localization length lambta 2on disorder, interaction strength and range is investigated. Our results demonstrate that the recently proposed enhancement of lambta 2 as compared to the results for single particles is vanishingly small for a Hubbard interaction. For longer-range interactions, we observe a small enhancement but with a different disorder dependence than proposed previously.

random potential chain

Hubbard

weak delocalization

MSC 60K40

ddc:530

Two interfacing particles in a random potential: The random model revisited

Vojta, T., Römer, R. A., Schreiber, M.

30 October 1998

We reinvestigate the validity of mapping the problem of two onsite interacting particles in a random potential onto an effective random matrix model. To this end we first study numerically how the non-interacting basis is coupled by the interaction. Our results indicate that the typical coupling matrix element decreases significantly faster with increasing single-particle localization length than is assumed in the random matrix model. We further show that even for models where the dependency of the coupling matrix element on the single-particle localization length is correctly described by the corresponding random matrix model its predictions for the localization length can be qualitatively incorrect. These results indicate that the mapping of an interacting random system onto an effective random matrix model is potentially dangerous. We also discuss how Imry's block-scaling picture for two interacting particles is influenced by the above arguments.

coupling matrix

random matrix model

random potential

Imry

MSC 60K40

ddc:530

No enhancement of the localization length for two interacting particles in a random potential

Römer, R. A., Schreiber, M.

30 October 1998

We study two interacting particles in a random potential chain by means of the transfer matrix method. The dependence of the two-particle localization length lampta_2 on disorder and interaction strength is investigated. Our results demonstrate that the recently proposed enhancement of lampta_2 as compared to the results for single particles is entirely due to the finite size of the systems considered. This is shown for a Hubbard-like onsite interaction and also a long-range interaction.

info:eu-repo/classification/ddc/530

ddc:530

potential chain

Hubbard,

MSC 60K40

The Mott-Anderson transition in the disordered one-dimensional Hubbard model

Pai, R. V., Punnoose, A., Römer, R. A.

30 October 1998

We use the density matrix renormalization group to study the quantum transitions that occur in the half-filled one-dimensional fermionic Hubbard model with onsite potential disorder. We find a transition from the gapped Mott phase with algebraic spin correlations to a gapless spin-disordered phase beyond a critical strength of the disorder 1 c ss U= 2. Both the transitions in the charge and spin sectors are shown to be coincident. We also establish the finite-size corrections to the charge gap and the spin-spin correlation length in the presence of disorder and using a finite-size-scaling analysis we obtain the zero temperature phase diagram of the various quantum phase transitions that occur in the disorder-interaction plane.

info:eu-repo/classification/ddc/530

ddc:530

matrix renormalization

Hubbard,

MSC 60K40

The two-dimensional Anderson model of localization with random hopping

Eilmes, A., Römer, R. A., Schreiber, M.

30 October 1998

We examine the localization properties of the 2D Anderson Hamiltonian with off-diagonal disorder. Investigating the behavior of the participation numbers of eigenstates as well as studying their multifractal properties, we find states in the center of the band which show critical behavior up to the system size N=200x200 considered. This result is confirmed by an independent analysis of the localization lengths in quasi-1D strips with the help of the transfermatrix method. Adding a very small additional onsite potential disorder, the critical states become localized.

info:eu-repo/classification/ddc/530

ddc:530

Hamiltonian

Anderson

eigenstates, multifractal

MSC 60K40

Weak delocalization due to long-range interaction for two electrons in a random potential chain

Römer, R. A., Schreiber, M.

30 October 1998

We study two interacting particles in a random potential chain by a transfer matrix method which allows a correct handling of the symmetry of the two- particle wave function, but introduces an artificial ¨bag¨ interaction. The dependence of the two-particle localization length lambta 2on disorder, interaction strength and range is investigated. Our results demonstrate that the recently proposed enhancement of lambta 2 as compared to the results for single particles is vanishingly small for a Hubbard interaction. For longer-range interactions, we observe a small enhancement but with a different disorder dependence than proposed previously.

info:eu-repo/classification/ddc/530

ddc:530

Two interfacing particles in a random potential: The random model revisited

Vojta, T., Römer, R. A., Schreiber, M.

30 October 1998

We reinvestigate the validity of mapping the problem of two onsite interacting particles in a random potential onto an effective random matrix model. To this end we first study numerically how the non-interacting basis is coupled by the interaction. Our results indicate that the typical coupling matrix element decreases significantly faster with increasing single-particle localization length than is assumed in the random matrix model. We further show that even for models where the dependency of the coupling matrix element on the single-particle localization length is correctly described by the corresponding random matrix model its predictions for the localization length can be qualitatively incorrect. These results indicate that the mapping of an interacting random system onto an effective random matrix model is potentially dangerous. We also discuss how Imry's block-scaling picture for two interacting particles is influenced by the above arguments.

info:eu-repo/classification/ddc/530

ddc:530

Imry

MSC 60K40