Condensed Matter Seminar: The Road to a Predictive Theory of Strongly Correlated Electron Materials

Abstract:

The prediction of the physical properties of solids  without  experimental input is a longstanding  challenge  in theoretical physics.  Weakly correlated  materials,  are  well understood in terms of the Fermi Liquid paradigm and  their properties can be accurately computed  with modern  implementations of density functional theory and perturbation theory in the screened Coulomb interactions, to the point that designing materials with desirable properties is now possible.   This paradigm fails  for a class of compounds, known as strongly correlated systems. 
Correlated electron systems are materials for which the previous paradigm fails dramatically. They continue to be discovered accidentally and  continue to  surprise us with their exceptional physical properties, ranging from high temperature superconductivity to anomalous thermoelectricity,  and their  potential for new  applications.  They pose  one of the most difficult non-perturbative challenges in physics. 
In this colloquium I   will give an elementary introduction to  the field of strongly correlated electron materials and  Dynamical Mean Field Theory (DMFT) a non perturbative method which provides a zeroth order picture of the strong correlation phenomena in close analogy with the Weiss mean field theory in statistical mechanics.  Applications  materials containing f and d electrons  will be presented.  We will  show how the anomalous properties of correlated materials emerge from their atomic constituents and  conclude with an outlook of the challenges ahead and the perspectives for a rational material design.

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