Abstract
Here, crystal structure, electronic structure, chemical substitution, pressure-dependent superconductivity, and thickness-dependent properties in FeSe-based superconductors are systemically reviewed. First, the superconductivity versus chemical substitution is reviewed, where the doping at Fe or Se sites induces different effects on the superconducting critical temperature (Tc). Meanwhile, the application of high pressure is extremely effective in enhancing Tc and simultaneously induces magnetism. Second, the intercalated-FeSe superconductors exhibit higher Tc from 30 to 46 K. Such an enhancement is mainly caused by the charge transfer from the intercalated organic and inorganic layer. Finally, the highest Tc emerging in single-unit-cell FeSe on the SrTiO3 substrate is discussed, where electron-phonon coupling between FeSe and the substrate could enhance Tc to as high as 65 K or 100 K. The step-wise increment of Tc indicates that the synergic effect of carrier doping and electron-phonon coupling plays a critical role in tuning the electronic structure and superconductivity in FeSe-based superconductors.
Highlights
After discovering FeAs-based superconductors in 2008 [1,2,3,4], a structurally-simple binary FeSe superconductor with a superconducting critical temperature (Tc ) of 8 K was quickly established byHsu et al [5] This brought researchers into a fresh new field of iron-based superconductors
The results showed that the removal of degeneracy in the 3dxz /3dyz bands occurred at temperatures close to the Ts, which may be the orbital origin of structural transition
In 2012, Wang et al reported that a single unit cell (SUC) FeSe film grown on a SrTiO3 (STO)
Summary
After discovering FeAs-based superconductors in 2008 [1,2,3,4], a structurally-simple binary FeSe superconductor with a superconducting critical temperature (Tc ) of 8 K was quickly established by. The binary compound is composed of a neutral FeSe layer that is composed of a FeSe4 tetrahedra along the c-axis, and the interlayer coupling is weak van der Waals forces. It was found, initially, that the chemical substitution of Se by S and Te mildly enhanced the Tc to 10−15 K. Apart from the enhancement of Tc , the angle resolve photoemission spectrum (ARPES) revealed that the Fermi surface in such high Tc superconductors share a common feature (i.e., only two electron pockets surviving at the M point).
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