AI Article Synopsis
- - The study investigates how energy flows between vibrational modes in gas-phase fluorobenzene after it's excited with a multi-THz pump, emphasizing the importance of anharmonic coupling.
- - It concludes that simple models based only on anharmonic coupling coefficients are insufficient, highlighting the need to consider the full motion of each mode during excitation.
- - The findings suggest that vibrational modes with A1 or B2 symmetry play a more significant role in energy transfer due to their favorable symmetry-allowed pathways.
Article Abstract
In this work, we study the energy flow through anharmonic coupling of vibrational modes after excitation of gas-phase fluorobenzene with a multi-THz pump. We show that to predict the efficiency of anharmonic energy transfer, simple models that only include the anharmonic coupling coefficients and motion of modes at their resonant frequency are not adequate. The full motion of each mode is needed, including the time while the mode is being driven by the pump pulse, because all the frequencies present in the multi-THz pump contribute to the excitation of the non-resonantly excited vibrational modes. Additionally, the model gives us the insight that modes with either A1 or B2 symmetry are more actively involved in anharmonic coupling because these modes have more symmetry-allowed energy transfer pathways.
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| http://dx.doi.org/10.1063/5.0159712 | DOI Listing |
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