Direct measurement of high-lying vibrational repumping transitions for molecular laser cooling

Abstract

Molecular laser cooling and trapping requires addressing all spontaneous decays to excited vibrational states that occur at the 10-4 - 10-5 level, which is accomplished by driving repumping transitions out of these states. However, the transitions must first be identified spectroscopically at high-resolution. A typical approach is to prepare molecules in excited vibrational states via optical cycling and pumping, which requires multiple high-power lasers. Here, we demonstrate a general method to perform this spectroscopy without the need for optical cycling. We produce molecules in excited vibrational states by using optically-driven chemical reactions in a cryogenic buffer gas cell, and implement frequency-modulated absorption to perform direct, sensitive, high-resolution spectroscopy. We demonstrate this technique by measuring the spectrum of the A21/2(1,0,0)-X2+(3,0,0) band in 174YbOH. We identify the specific vibrational repump transitions needed for photon cycling, and combine our data with previous measurements of the A21/2(1,0,0)-X2+(0,0,0) band to determine all of the relevant spectral constants of the X2+(3,0,0) state. This technique achieves high signal-to-noise, can be further improved to measure increasingly high-lying vibrational states, and is applicable to other molecular species favorable for laser cooling.