Over the past few years Fe chalcogenides (FeSe/Te) have advanced to the forefront of Fe-based superconductors (FeBS) research. The most intriguing results thus far are for intercalated and monolayer FeSe, however experimental studies are still inconclusive. Yet, bulk FeSe itself remains an unusual case when compared with pnictogen-based FeBS, and may hold clues to understanding the more exotic FeSederivatives. The FeSe phase diagram is unlike the pnictides: the orthorhombic distortion, which is likely to be of a "spin-nematic" nature in numerous pnictides, is not accompanied by magnetic order in FeSe, and the superconducting transition temperature Tc rises significantly with pressure before decreasing. In this paper we show that the magnetic interactions in chalcogenides, as opposed to pnictides, demonstrate unusual (and unanticipated) frustration, which suppresses magnetic, but not nematic order, favors ferroorbital order in the nematic phase and can naturally explain the nonmonotonic pressure dependence of the superconducting critical temperature Tc(P ).While full consensus regarding the mechanism of hightemperature superconductivity in Fe-based superconductors (FeBS) remains elusive, nearly all researchers agree that it is unconventional and that it has a magnetic origin 1,2 . However, there is a divergence of opinions on the nature of the electrons responsible for magnetism. There is an itinerant approach based on calculating the spin susceptibility with moderate Coulomb (Hubbard) and Hund's interactions [3][4][5][6][7][8][9][10] as well as a localized approach where itinerant electrons responsible for conduction and the Fermi surface interact with local spins 11,12 . Finally, there is an increasingly popular description where the electrons have a dual character and provide the local moments, the interaction between them, and the electronic conductivity [13][14][15][16] . Within this picture, FeBS can still be reasonably mapped onto a short-range model of pairwise interactions between the local moments.Following the discovery of the FeBS, there were multiple attempts to map the exchange interactions onto the Heisenberg model. The J 1 -J 2 model on the square lattice 17 with nearest-(J 1 ) and next-nearest-neighbor (J 2 ) exchange couplings was a natural starting point 18-21 , but required dramatically different couplings for ferro-and antiferromagnetic neighbors, J 1a J 1b to reproduce the observed spin waves 22,23 and ab-initio calculations 24 ; it also failed to describe the double-stripe configuration in FeTe 25,26 . The model was extended to include third-neighbor exchange J 3 27 to reproduce the FeTe magnetic ground state. However, only the Ising model has this configuration as a solution, and in the Heisenberg model it is not a ground state for any set of parameters 28,29 . Therefore adding J 3 does not solve the problem. Besides, the J 1a J 1b implies an unphysical temperature dependence of the exchange constants (as T approaches T N , by symmetry J 1a → J 1b ).There were attempts to overcome these pr...
