Magnetic trapping of metastable $^3P_2$ atomic strontium

A. Derevianko; A.L. Migdall; C. E. Simien; C.W. Oates; D.S. Weiss; E.L. Raab; G. Zinner; H. Katori; H. Katori; J. Grunert; J. Prodan; J. Stuhler; M. Bode; M. Machholm; M.P. Robinson; P. Gupta; S. B. Nagel; S. Laha; S.J.J.M.F. Kokkelmans; T. C. Killian; T. Loftus; T.C. Killian; T.P. Dinneen; V. S. Ashoka; W. Ketterle; W. Ketterle; Y. Isoya

research

Magnetic trapping of metastable $^3P_2$ atomic strontium

Authors: A. Derevianko
A.L. Migdall
C. E. Simien
C.W. Oates
D.S. Weiss
E.L. Raab
G. Zinner
H. Katori
H. Katori
J. Grunert
J. Prodan
J. Stuhler
M. Bode
M. Machholm
M.P. Robinson
P. Gupta
S. B. Nagel
S. Laha
S.J.J.M.F. Kokkelmans
T. C. Killian
T. Loftus
T.C. Killian
T.P. Dinneen
V. S. Ashoka
W. Ketterle
W. Ketterle
Y. Isoya
Publication date: 5 December 2002
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We report the magnetic trapping of metastable

^3P_2

atomic strontium. Atoms are cooled in a magneto-optical trap (MOT) operating on the dipole allowed

^1S_0-^1P_1

transition at 461 nm. Decay via

^1P_1\to {^1D_2}\to {^3P_2}

continuously loads a magnetic trap formed by the quadrupole magnetic field of the MOT. Over

10^8

atoms at a density of

8 \times 10^9

cm

^{-3}

and temperature of 1 mK are trapped. The atom temperature is significantly lower than what would be expected from the kinetic and potential energy of atoms as they are transferred from the MOT. This suggests that thermalization and evaporative cooling are occurring in the magnetic trap.Comment: This paper has been accepted by PR