Effect of CuO{sub 2} Lattice Strain on the Electronic Structure and Properties of High-T{sub c} Cuprate Family

Doping and strain dependences of the electronic structure of the CuO{sub 6}-octahedra layer within LDA+GTB method in the frameworks of six-band p-d model are calculated. Band structure and Fermi surface of the quasiparticle excitations in the effective Hubbard model are characterized by inhomogeneous distribution of the k-dependent spectral weight. Doping results in reconstruction of the band structure, redistribution of the spectral weight over dispersion surface, and reconstruction of Fermi surface from small hole pockets in the underdoped region to large hole contour in the overdoped region through two quantum phase transitions (QPT). Strain increasing leads to displacement of the valence and conductivity bands, bandwidths decreasing, and shift of the concentrations corresponding to QPTs. Strain dependences of the antiferromagnetic exchange coupling and DOS at the Fermi level determining superconducting temperature T{sub c} are obtained. Effective exchange coupling in the equation for T{sub c} demonstrates monotonic strain dependence.