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Abstract
Calculations are presented demonstrating controlled intermolecular communication between dopant molecules via lattice phonons in a cryogenic matrix. By simulating a time-resolved coherent anti-Stokes Raman scattering (tr-CARS) experiment on an I2-molecule ‘receiver,’ its reception from a Ca-atom ‘transmitter’ of coherent lattice waves in a compressed linear chain of Ar atoms is monitored. A short pulse resonant with an atomic transition in Ca arrives at the sample before the tr-CARS pulses, and the coherent response of the host medium to the electronic excitation sends a rarefaction wave through the lattice. The arrival of this propagating distortion at the I2 molecule is detected through the tr-CARS difference signal, the difference between tr-CARS signals with and without the Ca pulse. A normal-mode analysis of the equilibrium configuration is used to construct an initial Gaussian wave packet, which is propagated by locally quadratic approximations to the relevant many-body nuclear Hamiltonians. Results are presented for both resonant and sub-resonant excitation of the Ca atom. Calculations show a difference signal that turns on abruptly as the lattice wave generated by resonant Ca excitation reaches the I2 chromophore.
† Special number of Molecular Physics in honor of Robert A. Harris.
Acknowledgements
With admiration and appreciation, we dedicate this paper to the second author's former thesis advisor and life-long friend, Bob Harris. The research was supported by grants from the US National Science Foundation and the ACS-PRF, and a Fellowship to JAC from the J. S. Guggenheim Memorial Foundation. We gratefully acknowledge helpful advice from Professor David Herrick, University of Oregon, on the compact parametrization of the I2 RKR potentials, and many beneficial conversations with Ara Apkarian, UC-Irvine. We thank Professor Edward Caster, Rutgers University, who pointed out the connection between our work and the measurements of Citation25–28.
Notes
‡Current address: Walsh University, North Canton, OH 44720 USA.
† Special number of Molecular Physics in honor of Robert A. Harris.