Magic wavelengths and triple magic trapping conditions for 5s2~1\!S0 and 5s5p~3\!P0,2 states of Sr atoms
Abstract
The static and dynamic electric dipole polarizabilities of the 5s2~1\!S0 and 5s5p~3\!P0,2 states of Sr atoms are calculated using the relativistic configuration interaction plus the many-body perturbation theory (RCI+MBPT) method. Magic wavelengths are determined for the transitions 5s2~1\!S0→ 5s5p~3\!P0, 5s2~1\!S0→ 5s5p~3\!P2, and 5s5p~3\!P0→ 5s5p~3\!P2. A comprehensive study is conducted on the dependence of magic wavelengths on the angle between the laser polarization and the magnetic field. Furthermore, the conditions for realizing triple magic trapping at 813.4~nm for the 5s2~1\!S0, 5s5p~3\!P0 and 5s5p~3\!P2 states are investigated. In the case of linearly polarized light, when the angle (θp) between the laser polarization direction and the magnetic field is 79.1(0.7), triple magic trapping for the 5s2~1\!S0, 5s5p~3\!P0, and 5s5p~3\!P2~M=0 states can be achieved. This result agrees well with the recent experimental measurement (78.49(3))[Phys. Rev. Lett. 135, 143401 (2025)]. Meanwhile, triple magic trapping involving the 5s5p~3\!P2~M=2 state can be achieved when θp= 37.4(0.3). The conditions for achieving triple magic trapping with circularly and arbitrarily elliptically polarized light are also presented.
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