Strongly Correlated Systems

From GICC

A wide variety of interesting phenomena in physics can be described by a collection of particles that interact among each other, ranging from Celestial Mechanics to Elementary Particle Physics. These interactions are responsible for the complexity of the phenomena, making a theoretical description both challenging and interesting.

In some cases these interactions can be neglected, which allows an easier treatment of the problem that still describes the physical phenomena faithfully. This is the case of simple metals like copper where the conduction electrons are modeled in such a way that they can wander freely through the sample, and seldom interact with each other.

In some other cases the interaction must be taken into account to describe the system, but it is small enough to be treated approximately. This would be the case of dilute atomic gases and Bose-Einstein Condensation, where a Mean Field Theory can describe appropriately most of the observable effects [Pit03].

However in most of the cases these interactions are strong enough to establish certain correlations between the particles that are responsible of novel phenomena such as Magnetism, High Temperature Superconductivity, Quantum Phase Transitions, Fractional Quantum Hall effect, etc to name just a few [Aue94]. Strongly Correlated Systems is one of the major research areas in contemporary condensed-matter physics. However these high correlations are extremely difficult to deal with by theoretical means.

These correlations are profoundly related to the concept of Quantum Entanglement, which has turned out to be the central resource in quantum information processing responsible of phenomena like Quantum Teleportation, Superdense Coding, etc. The Quantum Information community has made an enormous effort to understand multiparticle entanglement , and as Preskill points out in [Pre00] we can benefit from the tools developed in order to get a better grasp of Strongly Correlated phenomena.

On the other hand the experimental realization of a device capable of outperforming classical computers (i.e. a quantum computer), sometimes relies on strongly correlated systems such as the Mott Insulating phase in an optical lattice, spin chains as quantum channels, etc.

The understanding of these systems is sometimes hindered by the inefficiency of numerical simulations in classical computers. A future solution shall be the use of a Universal Quantum Simulator (see section on Quantum simulation). However its experimental realization requires previous understanding of the particular system that may implement it.

It seems that we have come to a dead end; nevertheless we may use the tools developed by the Strongly Correlated community in order to find a way out. The key fact that prevents an efficient simulation of strongly correlated many-body systems is the huge number of degrees of freedom that must be treated. Using renormalization group techniques, we can get rid of the irrelevant degrees of freedom which are not responsible for the phenomena studied. In this case, we may get rid of high energy variables, since we are interested in low temperature physics. A numerical scheme capable of performing this renormalization preserving the strong correlations in the system was developed by Steven R. White [Whi92], and dubbed the Density Matrix Renormalization Group (DMRG).

One of the research interests in GICC is to investigate Strongly Correlated systems using the theoretical framework of Quantum Information science, as well as numerical techniques for classical computers based on the DMRG scheme.

Bibiliography

[Pit03] L.P. Pitaevskii, S. Stringari, " Bose-Einstein Condensation", Clarendon Press, Oxford, 2003.

[Aue94] A.Auerbach. "Interacting electrons and Magnetism", Springer, New York (1994)

[Pre00] J. Preskill. "Quantum information and physics: Some future directions". J. Mod. Opt., 47:127-137, 2000.

[Whi92] S.R.White,"Density Matrix ormulation for Quantum Renormalization Groups", Phys.Rev.Lett 69, 2863 , 1992.

GICC publications on this topic

"Numerical Computation of Localizable Entanglement in Spin Chains"

Popp, M.; Verstraete, F.; Martin-Delgado, M. A.; Cirac, I., Applied Physics B, Volume 82, Issue 2, pp.225-235, (2006) [1]

"Ground state cooling of atoms in optical lattices"

M. Popp, J. J. García-Ripoll, K. G. H. Vollbrecht, J. I. Cirac, Phys. Rev. A 74, 013622 (2006) [2]

"Localizable Entanglement"

M. Popp, F. Verstraete, M. A. Martin-Delgado, J. I. Cirac, Phys. Rev. A 71, 042306 (2005) [3]

"Universality Classes of Diagonal Quantum Spin Ladders"

M.A. Martin-Delgado, J. Rodriguez-Laguna, G. Sierra, Phys. Rev. B 72, 104435 (2005) [4]

"Diverging Entanglement Length in Gapped Quantum Spin Systems"

F. Verstraete, M.A. Martin-Delgado, J.I. Cirac, Phys. Rev. Lett. 92, 087201 (2004) [5]

"Matrix Product Density Operators: Simulation of finite-T and dissipative systems"

F. Verstraete, J. J. García-Ripoll, J. I. Cirac , Phys. Rev. Lett. 93, 207204 (2004) [6]

"Variational ansatz for the superfluid Mott-insulator transition in optical lattices"

J. J. García-Ripoll, C. Kollath, U. Schollwoeck, P. Zoller, J. von Delft, and J. I. Cirac, Optics Express 12, 42 (2004) [7]

``Distillation Protocols for Mixed States of Multilevel Qubits and the Quantum Renormalization Group"

M.A. Martin-Delgado, M. Navascues, Eur.Phys.J. D27 (2003) 169-180[8]

"Anderson transition in low-dimensional disordered systems driven by nonrandom long-range hopping"

A. Rodriguez, V.A. Malyshev, G. Sierra, M.A. Martin-Delgado, J. Rodriguez-Laguna, F. Dominguez-Adame, Phys. Rev. Lett. 90, 2, 027404 (1-4) (2003) [9]

"A Density Matrix Renormalization Group study of Excitons in Dendrimers"

M.A. Martin-Delgado, J. Rodriguez-Laguna, G. Sierra, Phys. Rev. B 65, 155116 (2002) [10]

"Exact diagonalisation study of charge order in the quarter-filled two-leg ladder system NaV2O5"

A. Langari, M. A. Martin-Delgado, P. Thalmeier, Phys. Rev. B 63, 144420 (2001) [11]

"Low Energy Properties of Ferrimagnetic 2-leg Ladders: a Lanczos study"

A. Langari, M.A. Martin-Delgado, Phys. Rev. B 63, 054432 (2001).

"Stripe Ansatzs from Exactly Solved Models"

M.A. Martin-Delgado, M. Roncaglia, G. Sierra, Phys. Rev. B 64, 075117 (2001).

"Single-Block Renormalization Group: Quantum Mechanical Problems"

M.A. Martin-Delgado, J. Rodriguez-Laguna, G. Sierra, Nuc. Phys. B 601, 569-590 (2001) [12]

"Matrix Product Approach to Conjugated Polymers "

M. A. Martin-Delgado, G. Sierra, S. Pleutin, E. Jeckelmann, Phys. Rev. B61, 1841, (2000) [13]

"The Density Matrix Renormalization Group applied to single particle Quantum Mechanics"

M.A. Martin-Delgado, G. Sierra and R.M. Noack, J. of Phys. A: Math. and Gen. 32, 6079 (1999) [14]

"The Matrix Product Approach to Quantum Spin Ladders"

J. M. Roman, G. Sierra, J. Dukelsky, M. A. Martin-Delgado, J. Phys. A : Math. Gen. 31, 9729-9759 (1998) [15]

"Equivalence of the Variational Matrix Product Method and the Density Matrix Renormalization Group applied to Spin Chains"

J. Dukelsky, M. A. Martin-Delgado, T. Nishino, G. Sierra, Europhysics Lett. 43 457, (1998) [16]