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Near-Infrared Light Triggered a High Temperature Utilizing Donor–Acceptor Cocrystals

Wenbin Chen, Li Dang, Zicong Situ, Shao‐Fei Ni, Yetao Chen, Sheng Zhu, Hailin Li, Shunli Chen, David Lee Phillips, Ming‐De Li

2022The Journal of Physical Chemistry Letters30 citationsDOI

Abstract

Developing a suitable initiation for the energetic materials that respond to a low-power near-infrared laser can aid in replacing the current expensive and bulky laser-initiation systems. Here, we report on a system of molecularly tailored 1:1 donor–acceptor (D-A) charge-transfer (CT) cocrystals that manifest ultrabroad absorption (200–2500 nm) characteristics as well as noteworthy very fast self-assembly behaviors. The very narrow highest occupied molecular orbital–lowest unoccupied molecular orbital gap enables N,N,N′,N′-tetramethyl-p-phenylenediamine and tetrahalo-1,4-benzoquinones (TMPD-TXBQ) cocrystals to have a great light-harvesting ability in the near-infrared range. When irradiated with a low-power hand-held 808 nm laser with an input energy of only 40 mJ or a power density of 260 mW·cm–2, these TMPD-TXBQ cocrystals immediately undergo an efficient photothermal conversion followed by a dramatic exothermic thermal polymerization reaction due to the face-to-face D-A-D-A stacking in these cocystals to achieve a temperature as high as 318.9 °C. This temperature is high enough for a thermal initiation of most common energetic materials, and thus this TMPD-TXBQ cocrystal can potentially act as a near-infrared laser initiator that is compact, lightweight, and cost-effective.

Topics & Concepts

CocrystalMaterials sciencePhotochemistryLaserInfraredAcceptorStackingOptoelectronicsChemistryMoleculeOpticsOrganic chemistryCondensed matter physicsPhysicsHydrogen bondEnergetic Materials and CombustionNonlinear Optical Materials StudiesLuminescence and Fluorescent Materials