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W2987326065 abstract "Two-dimensional layered halide organic perovskites (LHOPs) are promising candidates for many optoelectronic applications due to their interesting tunable properties. They provide a unique opportunity to control energy and charge dynamics via the independent tunability of the energy levels within the perovskite and the organic spacer for various optoelectronic applications. In the perovskite layer alone, one can replace the Pb (Sn), the halide (X = I, Br, Cl), the organic component, and the number of layers between the organic spacer layers. In addition, there are many possibilities for organic spacer layers between the perovskite layers, making it difficult for experimental methods to comprehensively explore such an extensive combinatorial space. Of particular technological interest is alignment of electronic levels between the perovskite layer and the organic spacer layer, leading to desired transfer of energy or charge carriers between perovskite and organic components. For example, as band edge absorption is almost entirely attributed to the perovskite layer, one way to demonstrate energy transfer is to observe triplet emission from organic spacers. State-of-the-art computational chemistry tools can be used to predict the properties of many stoichiometries in search for LHOPs that have the most promising electronic-structure features. In this first-principles study, we survey a group of π-conjugated organic spacer candidates for use in triplet light-emitting LHOPs. Utilizing density functional theory (DFT) and time-dependent DFT, we calculate the first singlet (S1) and triplet (T1) excitation energy in the ground-state geometry and the first triplet excitation energy in the excited-triplet-state relaxed geometry (T1*). By comparing these energies to the known lowest exciton energy level of PbnX3n+1 perovskite layers (X = I, Br, Cl), we can identify organic spacer and perovskite layer pairings for possible transfer of Wannier excitons from the inorganic perovskite lattice to spin-triplet Frenkel excitons located on the organic cation. We successfully identify ten organic spacer candidates for possible pairing with perovskite layers of specific halide composition to achieve triplet light emission across the visible energy range. Molecular dynamics simulations predict that finite temperatures and perovskite environment have little influence on the average excitation energies of the two common organic spacers naphthylethylammonium (NEA) and phenelethylammonium (PEA). We find significant thermal broadening up to 0.5 eV of the optical excitation energies appearing due to finite temperature effects. The findings herein provide insights into alignment of electronic levels of the conjugated organic spacer with the layer." @default.
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W2987326065 date "2019-11-01" @default.
W2987326065 modified "2023-10-16" @default.
W2987326065 title "Tuning Electronic Structure in Layered Hybrid Perovskites with Organic Spacer Substitution" @default.
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W2987326065 cites W1981368803 @default.
W2987326065 cites W1985430119 @default.
W2987326065 cites W1989940072 @default.
W2987326065 cites W1993980724 @default.
W2987326065 cites W1997151511 @default.
W2987326065 cites W2004007900 @default.
W2987326065 cites W2007395042 @default.
W2987326065 cites W2015053669 @default.
W2987326065 cites W2033597029 @default.
W2987326065 cites W2035579953 @default.
W2987326065 cites W2038767330 @default.
W2987326065 cites W2044591029 @default.
W2987326065 cites W2044940178 @default.
W2987326065 cites W2050941823 @default.
W2987326065 cites W2051453900 @default.
W2987326065 cites W2055325187 @default.
W2987326065 cites W2056047920 @default.
W2987326065 cites W2061977204 @default.
W2987326065 cites W2062852634 @default.
W2987326065 cites W2063564843 @default.
W2987326065 cites W2064362837 @default.
W2987326065 cites W2076220745 @default.
W2987326065 cites W2076757103 @default.
W2987326065 cites W2079105963 @default.
W2987326065 cites W2083222334 @default.
W2987326065 cites W2085093563 @default.
W2987326065 cites W2085810523 @default.
W2987326065 cites W2094517427 @default.
W2987326065 cites W2114911094 @default.
W2987326065 cites W2143981217 @default.
W2987326065 cites W2150702843 @default.
W2987326065 cites W2264327221 @default.
W2987326065 cites W2316117939 @default.
W2987326065 cites W2332549384 @default.
W2987326065 cites W2335099625 @default.
W2987326065 cites W2533429430 @default.
W2987326065 cites W2591676480 @default.
W2987326065 cites W2594008253 @default.
W2987326065 cites W2740451316 @default.
W2987326065 cites W2781863821 @default.
W2987326065 cites W2786103938 @default.
W2987326065 cites W2788074397 @default.
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W2987326065 doi "https://doi.org/10.1021/acs.nanolett.9b03427" @default.
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