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Infrared spectroscopy of endohedral water in C$_{60}$

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 Added by Toomas R\\~o\\~om
 Publication date 2021
  fields Physics
and research's language is English




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Infrared absorption spectroscopy study of endohedral water molecule in a solid mixture of H$_2$O@C$_{60}$ and C$_{60}$ was carried out at liquid helium temperature. From the evolution of the spectra during the ortho-para conversion process, the spectral lines were identified as para- and ortho-water transitions. Eight vibrational transitions with rotational side peaks were observed in the mid-infrared: $omega_1$, $omega_2$, $omega_3$, $2omega_1$, $2omega_2$, $omega_1 +omega_3$, $omega_2 +omega_3$, and $2omega_2+omega_3$. The vibrational frequencies $omega_2$ and 2$omega_2$ are lower by 1.6% and the rest by 2.4%, as compared to free water/. A model consisting of a rovibrational Hamiltonian with the dipole and quadrupole moments of water interacting with the crystal field was used to fit the infrared absorption spectra. The electric quadrupole interaction with the crystal field lifts the degeneracy of the rotational levels. The finite amplitudes of the pure $v_1$ and $v_2$ vibrational transitions are consistent with the interaction of the water molecule dipole moment with a lattice-induced electric field. The permanent dipole moment of encapsulated water/ is found to be $0.5pm 0.1$ D as determined from the far-infrared rotational line intensities. The translational mode of the quantized center of mass motion of water/ in the molecular cage of C$_{60}$ was observed at 110cm$^{-1}$ (13.6meV).



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We report the observation of quantized translational and rotational motion of molecular hydrogen inside the cages of C60. Narrow infrared absorption lines at the temperature of 6K correspond to vibrational excitations in combination with translational and rotational excitations and show well resolved splittings due to the coupling between translational and rotational modes of the endohedral H2 molecule. A theoretical model shows that H2 inside C60 is a three-dimensional quantum rotor moving in a nearly spherical potential. The theory provides both the frequencies and the intensities of the observed infrared transitions. Good agreement with the experimental results is obtained by fitting a small number of empirical parameters to describe the confining potential, as well as the ortho to para ratio.
112 - R. T. Harding , A. Folli , J. Zhou 2017
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