Classical description of angular-momentum motion due to optical pumping
Abstract
The Wigner representation of angular-momentum orientation in the classical limit on J>>1 has been used to derive an equation of angular-momentum motion in the case of a closed two-level system interacting with an arbitrary polarized radiation. This equation enables us to carry out a theoretical analysis of angular-momentum motion and consider final states of the quantum system for all types of dipole transitions. We have found that in the case of a zero magnetic field in the final state of the system with J-->J or J-->J+1 optical transition, the angular momentum is directed along or opposite to the wave vector of the radiation depending on the sign of the polarization ellipsity, while for a linear polarization the angular momentum is isotropically distributed on the plane orthogonal to the polarization vector. For the J-->J-1 transition two directions of angular momentum are possible in the final state. These directions are determined by the ellipsity of polarization. The spatial size of the final distribution of the angular momentum has been defined by the quantum uncertainty, 1/J, of the angular-momentum orientation. In the case of the J-->J-1 or J-->J, transition particles come into ``dark'' states while for the J-->J+1 transition they occupy the ``brightest'' state. In the presence of a nonzero magnetic field, particles with J-->J transition have in the final state only one angular-momentum orientation, i.e., along or opposite to the direction of the magnetic field depending on the polarization ellipsity sign. For the J-->J+1 transition both directions are possible, i.e., along and opposite to the magnetic field. In the case of the J-->J-1 transition the directions of the angular momentum form a cone around the magnetic field.
- Publication:
-
Physical Review A
- Pub Date:
- April 2001
- DOI:
- 10.1103/PhysRevA.63.043406
- Bibcode:
- 2001PhRvA..63d3406N
- Keywords:
-
- 32.80.-t;
- 03.65.Sq;
- 33.80.Be;
- Photon interactions with atoms;
- Semiclassical theories and applications;
- Level crossing and optical pumping