The iron based superconductors (FeSC) promise interesting physics and applications, and, while the interplay of superconductivity and magnetism, as well as their mechanisms remain the issues of active debates and studies, one thing in FeSC puzzle is clear, namely that it is the complex multi-band electronic structure of these compounds that determines their rich and puzzling properties [1, 2]. What is important and fascinating is that this complexity seems to play a positive role in the struggle for understanding the FeSC physics and also for search of the materials with higher Tc's. This is because the multiple electronic bands and resulting complex Fermiology offer exceptionally rich playground for establishing useful empirical correlations. This is also because this electronic structure is well understood—the band structure calculations well reproduce its complexity: all the bands and their symmetry. The role of the experiment, in this case, is just to define the exact position and renormalization for each band. This piece of experimental knowledge, however, appears to be vitally important for understanding of the electronic properties of these new compounds.
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机译:铁基超导体(FeSC)有望实现有趣的物理和应用,并且尽管超导性和磁性的相互作用以及它们的机理仍然是活跃的辩论和研究问题,但FeSC难题中的一件事很清楚,那就是它是这些化合物的复杂多带电子结构决定了它们的丰富和令人困惑的特性[1、2]。重要且引人入胜的是,这种复杂性似乎在努力理解FeSC物理以及寻找具有更高T c 的材料的斗争中发挥了积极作用。这是因为多个电子波段以及由此产生的复杂费米学为建立有用的经验相关性提供了异常丰富的场所。这也是因为这种电子结构已广为人知-频带结构的计算很好地重现了其复杂性:所有频带及其对称性。在这种情况下,实验的作用只是定义每个频段的确切位置和重新规范化。然而,这一实验知识似乎对于理解这些新化合物的电子性质至关重要。
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