The SU (4)−SU (2) crossover, driven by an external magnetic field h, is analyzed in a capacitivelycoupled double-quantum-dot device connected to independent leads. As one continuously charges the dots from empty to quarter-filled, by varying the gate potential Vg, the crossover starts when the magnitude of the spin polarization of the double quantum dot, as measured by n ↑ − n ↓ , becomes finite. Although the external magnetic field breaks the SU (4) symmetry of the Hamiltonian, the ground state preserves it in a region of Vg, where n ↑ − n ↓ = 0. Once the spin polarization becomes finite, it initially increases slowly until a sudden change occurs, in which n ↓ (polarization direction opposite to the magnetic field) reaches a maximum and then decreases to negligible values abruptly, at which point an orbital SU (2) ground state is fully established. This crossover from one Kondo state, with emergent SU (4) symmetry, where spin and orbital degrees of freedom all play a role, to another, with SU (2) symmetry, where only orbital degrees of freedom participate, is triggered by a competition between gµBh, the energy gain by the Zeeman-split polarized state and the Kondo temperature T SU (4) K , the gain provided by the SU (4) unpolarized Kondo-singlet state. At fixed magnetic field, the knob that controls the crossover is the gate potential, which changes the quantum dots occupancies. If one characterizes the occurrence of the crossover by V max g , the value of Vg where n ↓ reaches a maximum, one finds that the function f relating the Zeeman splitting, Bmax, that corresponds to V max g , i.e., Bmax = f V max g , has a similar universal behavior to that of the function relating the Kondo temperature to Vg. In addition, our numerical results show that near the SU (4) Kondo temperature and for relatively small magnetic fields the device has a ground state that restricts the electronic population at the dots to be spin polarized along the magnetic field. These two facts introduce very efficient spin-filter properties to the device, also discussed in detail in the paper. This phenomenology is studied adopting two different formalisms: the Mean Field Slave Bosons Approximation, which allows an approximate analysis of the dynamical properties of the system, and a Projection Operator Approach, which has been shown to describe very accurately the physics associated to the ground state of Kondo systems.
