摘要
We measure the rotational populations of ultracold SS Rbla3 Cs molecules in the lowest vibrational ground state by a depletion spectroscopy and quantify the molecular production rate based on the measurement of single ion signal area. The SSRb133Cs molecules in the X1∑+(v = 0) are formed from the short-range (2)^3П0+(V = 10, J = 0) molecular state. A home-made external-cavity diode laser is used as the depletion laser to measure the rotational populations of the formed molecules. Based on the determination of single ion signal, the production rates of molecules in the J=0 and J = 2 rotational levels are derived to be 4800mole/s and 7200mole/s, respectively. The resolution and quantification of molecules in rotational states are facilitative for the manipulation of rotational quantum state of ultracold molecules.
We measure the rotational populations of ultracold SS Rbla3 Cs molecules in the lowest vibrational ground state by a depletion spectroscopy and quantify the molecular production rate based on the measurement of single ion signal area. The SSRb133Cs molecules in the X1∑+(v = 0) are formed from the short-range (2)^3П0+(V = 10, J = 0) molecular state. A home-made external-cavity diode laser is used as the depletion laser to measure the rotational populations of the formed molecules. Based on the determination of single ion signal, the production rates of molecules in the J=0 and J = 2 rotational levels are derived to be 4800mole/s and 7200mole/s, respectively. The resolution and quantification of molecules in rotational states are facilitative for the manipulation of rotational quantum state of ultracold molecules.
基金
Supported by the National Key Research and Development Program of China under Grant No 2017YFA0304203
the National Natural Science Foundation of China under Grant Nos 61675120,11434007 and 61378015
the Program for Changjiang Scholars and Innovative Research Team in University under Grant No IRT13076
the Applied Basic Research Project of Shanxi Province under Grant No 201601D202008
作者简介
Corresponding author. Email: zhaoyt@sxu.edu.cn
