The Nematic Energy Scale and the Missing Electron Pocket in FeSe

The multi-orbital nature of iron-based superconductors plays an important role in the fundamental physics of these materials. FeSe, while having the simplest structure among these materials, exhibits the effects of both nematicity and orbital-selective electron correlations. Here we report a study of both aspects in FeSe by performing an angle-resolved photoemission spectroscopy measurement on fully detwinned single crystals of FeSe. Our data clearly demonstrate that a nematicity-driven band reconstruction occurs in the low temperature orthorhombic state. As a direct result of this band reconstruction, the energy difference between the dxz and dyz bands reach 50 meV at the Brillouin zone boundary and the fate of the missing dxz electron pocket is naturally explained. Thus the nematicity-driven band reconstruction in our data provides a clear and accurate basis for theoretical models for understanding superconducting pairing in FeSe.