Elastic and inelastic collisions of C<sub>60</sub> in buffer gases probed by nonlinear spectroscopy
ORAL
Abstract
C60, comprising 60 indistinguishable carbon atoms arranged on a spherical lattice, straddles the border between a molecule and extended material. Nonetheless, its rigid symmetrical structure makes it by far the largest molecule for which rotational quantum state resolution has been achieved [1].
We have developed sensitive and nonlinear mid-infrared rovibrational spectroscopy to further probe and manipulate quantum states of buffer gas-cooled C60. Nonlinear absorption spectra reveal signatures of elastic and inelastic cross sections of the C60 - buffer gas collisions. While the enormous vibrational partition function of C60 demands use of heavier buffer gases, preliminary results suggest that effective rotational cooling may be achieved with gases of lighter atoms and molecules. These results may pave the way for efficient buffer gas cooling of unprecedentedly large molecules and establish C60 as a new platform for quantum science.
[1] P. B. Changala, M. L. Weichman, K. F. Lee, M. E. Fermann, J. Ye, Science 363, 49 (2019)
We have developed sensitive and nonlinear mid-infrared rovibrational spectroscopy to further probe and manipulate quantum states of buffer gas-cooled C60. Nonlinear absorption spectra reveal signatures of elastic and inelastic cross sections of the C60 - buffer gas collisions. While the enormous vibrational partition function of C60 demands use of heavier buffer gases, preliminary results suggest that effective rotational cooling may be achieved with gases of lighter atoms and molecules. These results may pave the way for efficient buffer gas cooling of unprecedentedly large molecules and establish C60 as a new platform for quantum science.
[1] P. B. Changala, M. L. Weichman, K. F. Lee, M. E. Fermann, J. Ye, Science 363, 49 (2019)
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Presenters
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Lee Liu
- University of Colorado, Boulder