2017
DOI: 10.1039/c7cc02322g
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Long alkyl side-chains impede exciton interaction in organic light harvesting crystals

Abstract: Side-chains at the imidic position of naphthalimide rendered a firm control over (i) the degrees of π-π overlap and (ii) distances between the perylenimide units in a crystalline naphthalimide-perylenimide dyad as determined using single crystal XRD and Hirshfeld surface analyses. Steady-state and time-resolved electronic spectroscopy in addition to DFT calculations revealed a decline in intermolecular excitonic interaction due to interfering alkyl chains.

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Cited by 21 publications
(10 citation statements)
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“…Such ultralong phosphorescence shows steady-state optical behavior. [25] To the best of our knowledge,r esearchers have yet to find am olecular system capable of dynamic ultralong phosphorescence.I nspired by the rational manipulation of molecular stacking by alkyl-chain engineering [26] and dynamic motion in crystalline molecule machines, [27] we speculate herein that dynamic organic phosphorescence might be induced by harvesting the synergistic effects of intermolecular interactions and molecular motion within an ew class of molecular rotors resting in the crystalline state.B ymeans of photoirradiation in the crystalline state to manipulate intermolecular interactions,d ynamic optical behavior may be realized to stabilize triplet excitons for ultralong phosphorescence through molecular motion.…”
mentioning
confidence: 99%
“…Such ultralong phosphorescence shows steady-state optical behavior. [25] To the best of our knowledge,r esearchers have yet to find am olecular system capable of dynamic ultralong phosphorescence.I nspired by the rational manipulation of molecular stacking by alkyl-chain engineering [26] and dynamic motion in crystalline molecule machines, [27] we speculate herein that dynamic organic phosphorescence might be induced by harvesting the synergistic effects of intermolecular interactions and molecular motion within an ew class of molecular rotors resting in the crystalline state.B ymeans of photoirradiation in the crystalline state to manipulate intermolecular interactions,d ynamic optical behavior may be realized to stabilize triplet excitons for ultralong phosphorescence through molecular motion.…”
mentioning
confidence: 99%
“…The latter approach relies on the fact that changing the alkyl chain length of a molecular system could tune the crystal packing mode and thus the electronic properties in the solid-state. [19][20][21][22] The results reported herein show that the combined treatments of mechanical grinding and aniline vapor fuming on PAP-Cn (n = 4, 8, 12, or 16) result in the formation of a three-component PAP-Cn/PAP-Cn/ aniline complex (triplex). In addition, mechanical grinding increases the retention time for the aniline guest in the films.…”
Section: Introductionmentioning
confidence: 73%
“…In this context, the intriguing polymorph-dependentP MFC properties of 1-C8 prompted us to furtheri nvestigate the crystal polymorphisma nd both the local and bulk photomechanical effects of this p system.O ne of our approaches is to vary the alkyl chain length,a st his has been au seful strategy for structurala nd property engineering of solid-state materials. [36][37][38] Accordingly,c ompounds 1-Cn (n = 4, 7-13, 16), where n refers to the number of carbon atoms in the linear alkyl chain, were studied. The results reported herein show that the alkyl chain length affects not only the crystal packing mode but also the lattice stiffness.…”
Section: Introductionmentioning
confidence: 99%