Abstract
Singlet exciton fission (SEF) is a key process for developing efficient optoelectronic devices. An aspect rarely probed directly, yet with tremendous impact on SEF properties, is the nuclear structure and dynamics involved in this process. Here, we directly observe the nuclear dynamics accompanying the SEF process in single crystal pentacene using femtosecond electron diffraction. The data reveal coherent atomic motions at 1 THz, incoherent motions, and an anisotropic lattice distortion representing the polaronic character of the triplet excitons. Combining molecular dynamics simulations, time-dependent density-functional theory, and experimental structure factor analysis, the coherent motions are identified as collective sliding motions of the pentacene molecules along their long axis. Such motions modify the excitonic coupling between adjacent molecules. Our findings reveal that long-range motions play a decisive part in the electronic decoupling of the electronically correlated triplet pairs and shed light on why SEF occurs on ultrafast time scales.
Highlights
Organic molecular semiconductors have unique optoelectronic properties, combining the intrinsic optical characteristics of the individual molecules with the long-range correlations enabled by intermolecular coupling
We directly reveal the structural dynamics accompanying the singlet exciton fission (SEF) process in single crystal pentacene using the method of femtosecond electron diffraction (FED), supported by real-time time-dependent density-functional theory (RT-TDDFT) and molecular dynamics simulations (MDS)
Pentacene (C22H14) single crystals were grown by sublimation, giving rise to a triclinic crystal structure [25, 26]
Summary
Organic molecular semiconductors have unique optoelectronic properties, combining the intrinsic optical characteristics of the individual molecules with the long-range correlations enabled by intermolecular coupling. Among these properties, the ability of several organic semiconductors to undergo singlet exciton fission (SEF) has drawn tremendous fundamental and applied research interest over the past decades, summarized in several review articles [1,2,3,4]. SEF is the process by which an electronically excited singlet exciton S1 spontaneously splits into two triplet states T1 + T1. The current understanding of the process involves three steps [1, 6]
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