<h4 align="center">WIGNER SZFI SZEMINÁRIUM</h4>
<h2 align="center">JOHANNES RICHTER</h2>
<p align="center">(Institut fur Theoretische Physik, Universitat Magdeburg, Germany, vendéglátó: Penc Karlo)</p>
<h2 align="center">"Strongly correlated systems on highly frustrated lattices: The flat-band scenario and beyond"</h2>
<p align="center">Időpont: 2015. március 26. (csütörtök) 14:00 (1 óra)<br>
Hely: MTA Wigner FK SZFI, I. épület 1. emeleti Tanácsterem</p>
<h3>Összefoglaló:</h3>
<p>Frustration in magnetic and electronic systems may lead to dispersionless (flat) one-particle bands which have a strong influence on the many-body physics of strongly correlated quantum systems. Thus, flat-band systems are receiving a great deal of attention right now, in particular with view of realizing new many-body phases there. In my talk I will give an overview on the low-temperature physics of flat-band Heisenberg spin systems and Hubbard electrons. <br />Interestingly for a large variety of such strongly correlated quantum systems a class of exact many-body eigenstates of localized nature can be constructed. Examples are the 1D sawtooth and kagome chains, the 2D kagome and checkerboard lattices, and the 3D pyrochlore lattice. The correlated quantum systems having localized eigenstates exhibit a highly degenerate ground-state manifold leading to a residual entropy. <br />By mapping relevant low-energy degrees of freedom of the quantum system at hand onto a corresponding classical hard-core lattice gas one can apply the toolbox of classical statistical mechanics to describe the low-temperature properties of the quantum system. Though the flat-band scenario has some common features for spin and electron systems, the different statistics of spins and electrons leads to different construction rules for the localized many-body eigenstates and, as a result, to a different hard-core lattice gas description. For electrons the scenario of localized eigenstates is related to the so-called flat-band ferromagnetism. For spin systems the localized many-body states lead to some spectacular features in strong magnetic fields, such as zero-temperature magnetization plateaus and jumps, magnetic-field driven spin-Peierls lattice instabilities, an extra peak in the specific heat at low temperatures as well as to an enhanced magnetocaloric effect. <br />In real systems typically the ideal flat-band geometry is distorted and the above illustrated features are modified. However, for small distortions the basic low-temperature features are still present which is relevant for the experimental access to the physical properties related to the flat band.<br /><br />For a recent review, see O. Derzhko, J. Richter and M. Maksymenko, arXiv:1502.02729.</p>
<p><b>Részletes információ:</b>
<a href="http://www.szfki.hu/seminar">http://www.szfki.hu/seminar</a></p>
<h4 align="center">Minden érdeklődőt szívesen látunk!</h4><p align="center">Asbóth János<br>szfi-seminar@wigner.mta.hu</p><p> </p>