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Abstract
Energy conversion in energetic materials from shockwave-induced lattice compression to bond breaking critically depends on vibrational coupling and energy transfer between intra- and intermolecular vibrations, though the details of the mechanisms remain unknown. Herein, we indirectly tune the strength of intermolecular interactions in 3,4-bis(3-nitrofurazan-4-yl)furoxan (BNFF), a hydrogen-free energetic material characterized by van der Waals interactions, by applying high static pressure using a diamond anvil cell and monitoring vibrational energy transfer (VET) with ultrafast broadband infrared pump-probe spectroscopy. As BNFF is compressed from ambient pressure to 9 GPa, we find VET accelerates by ~0.9 ps/GPa. Density functional theory is applied in tandem with experiment to assign mode character and elucidate VET pathways. We find that furazan ring O-N-O vibrations, which are high-frequency detonation-relevant vibrational modes, experience increased sensitivity to lattice compression under shockwave pressures. These findings provide new mechanistic insight into how intermolecular interactions govern the rate and selectivity of VET.
Supplementary materials
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Supporting Information
Description
Details of the sample preparation; experimental and theoretical methods; theoretical results; additional experimental results; discussion of kinetic modeling and fitting; and details and discussion of analysis of the long-time dynamic
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