Continuum of many-particle states near the metal-insulator transition in the Hubbard model

The strong coupling diagram technique is used for investigating states near the metal-insulator transition in the half-filled two-dimensional repulsive Hubbard model. The nonlocal third-order term is included in the irreducible part along with local terms of lower orders. Derived equations for the electron Green's function are solved by iteration for moderate Hubbard repulsions and temperatures. Starting iteration from Green's functions of the Hubbard-I approximation with various distances of poles from the real frequency axis continua of different metallic and insulating solutions are obtained. The insulating solutions vary in the width of the Mott gap, while the metallic solutions differ in the shape of the spectral function in the vicinity of the Fermi level. Besides, different scenarios of the metal-insulator transition -- with a sudden onset of a band of mobile states near the Fermi level and with gradual closure of the Mott gap -- are observed with a change in temperature. In spite of these dissimilarities, all solutions have a common curve separating metallic and insulating states in the phase diagram. Near this curve metallic and insulating solutions coexist. For moderate Hubbard repulsions metallic solutions are not Fermi liquids.Comment: 10 pages, 9 figure

Magnetic properties and temperature variation of spectra in the Hubbard model

Using the strong coupling diagram technique, magnetic and spectral properties of the two-dimensional repulsive Hubbard model are investigated in the ranges of repulsions $t\leq U\leq 10t$, temperatures $0.1t\lesssim T\lesssim 4t$ and electron concentrations $0.6\lesssim\bar{n}\leq 1$ with $t$ the hopping constant. The approach takes into account interactions of electrons with spin and charge fluctuations of all ranges and fulfils the Mermin-Wagner theorem. Temperature and concentration dependencies of the uniform magnetic susceptibility, the variation of the double occupancy with the repulsion and the temperature dependence of the square of the site spin are in satisfactory agreement with Monte Carlo results. Three types of the temperature variation of the electron energy spectrum can be distinguished at half-filling. For $U\lesssim 3t$, at low temperatures, there are two nonintersecting bands, which approach each other on the boundary of the magnetic Brillouin zone. With increasing $T$ these bands merge into one band crossing the Fermi level. For $4t\lesssim U \lesssim 6t$, the low-temperature picture described above is supplemented with a low-intensity spin-polaron band located near the Fermi level. As its counterpart in the strong-correlation case, the band is formed by bound states of electrons and spin excitations. However, in contrast to the former case, the band exists even at half-filling and occupies the entire Brillouin zone. As for lower $U$, with increasing temperature, all bands coalesce into a single band. For $U\gtrsim 7t$ and low temperatures the spectrum has a pronounced four-band structure, which with increasing $T$ transforms into two Hubbard subbands.Comment: 12 pages, 14 figure

Cooling by conversion of para to ortho-hydrogen

The cooling capacity of a solid hydrogen cooling system is significantly increased by exposing vapor created during evaporation of a solid hydrogen mass to a catalyst and thereby accelerating the endothermic para-to-ortho transition of the vapor to equilibrium hydrogen. Catalyst such as nickel, copper, iron or metal hydride gels of films in a low pressure drop catalytic reactor are suitable for accelerating the endothermic para-to-ortho conversion