Coupled quantum dots as quantum gates

We consider a quantum-gate mechanism based on electron spins in coupled semiconductor quantum dots. Such gates provide a general source of spin entanglement and can be used for quantum computers. We determine the exchange coupling (Formula presented) in the effective Heisenberg model as a function of magnetic (Formula presented) and electric fields, and of the interdot distance (Formula presented) within the Heitler-London approximation of molecular physics. This result is refined by using (Formula presented) hybridization, and by the Hund-Mulliken molecular-orbit approach, which leads to an extended Hubbard description for the two-dot system that shows a remarkable dependence on (Formula presented) and (Formula presented) due to the long-range Coulomb interaction. We find that the exchange (Formula presented) changes sign at a finite field (leading to a pronounced jump in the magnetization) and then decays exponentially. The magnetization and the spin susceptibilities of the coupled dots are calculated. We show that the dephasing due to nuclear spins in GaAs can be strongly suppressed by dynamical nuclear-spin polarization and/or by magnetic fields.