Using DFT Methods to Study Activators in Optical Materials

Du, Mao‐Hua

doi:10.1149/2.0011601jss

Cited by 31 publications

(22 citation statements)

References 113 publications

(233 reference statements)

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“…Along the axis of the tube, the band dispersion is still small, reflecting the weakened Pb–Br hybridization due to the distortion of the PbBr 6 octahedral structure. The narrow bands near the band edges and the soft lattice of (HTMA) 3 Pb 2 Br 7 should favor charge localization and the formation of self-trapped excitons, 37 – 39 which is consistent with the absence of free exciton emission at room temperature. The top of the valence band is mostly made up of Br-4p states but has significant Pb-6s character, while the bottom of the conduction band is dominated by Pb-6p states as shown by the projected density of states (DOS) in Fig.…”

Section: Resultssupporting

confidence: 61%

Bulk assembly of organic metal halide nanotubes

et al. 2017

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Section: Resultssupporting

confidence: 61%

Bulk assembly of organic metal halide nanotubes

et al. 2017

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“…As shown in Figure a, the dispersion curves are flat for most of the directions in the first Brillouin zone, which reflects the 1D character of the crystal structure. The narrow VBs and CBs favor the localization of the charge carriers and the formation of self‐trapped excitons (STEs) …”

Section: Resultsmentioning

confidence: 99%

Negative Thermal Quenching of Efficient White‐Light Emission in a 1D Ladder‐Like Organic/Inorganic Hybrid Material

Barkaoui

Abid

Zelewski

et al. 2019

Advanced Optical Materials

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semiconducting properties as well as their ability to process materials using low temperature techniques. [6][7][8][9] Their crystal structures generally consist of layered metal halide sheets alternating with organic cations. The inorganic and organic components are linked by hydrogen bonds to form the perovskite-like structure. [10][11][12] White-light emission has been recently discovered in several 2D OIH layered perovskites and has been attributed to the self-trapping of excitons within the hybrid material. [13][14][15][16][17][18][19][20][21][22] This important discovery sets the stage for exploring white-light emitting diodes (WLEDs) based on such materials which exhibit a photoluminescence (PL) quantum yield (QY) that can reach 32.5%. [23] However, since the first reports of 1D OIH compounds in 1995 by Papavassiliou et al. and Mitzi et al.,[24,25] investigations of these low-dimensional materials have remained scarcely reported, despite their many benefits such as high exciton stability, strong quantum confinement, and their ability to combine various types of sharing metal halide octahedral within a single chain. Yet, it can be denoted that 1D materials have regained an increasing interest for the last 2 years The synthesis and the optical properties of a new organic-inorganic hybrid material (C 6 H 22 N 4 )[Pb 2 Br 8 ] (abbreviated as TETAPb 2 Br 8 ) is reported here.Its ladder-like crystal structure is built up from infinite 1D chains of cornersharing [Pb 2 Br 8 ] 4− bi-octahedra surrounded by tetra-protonated triethylenetetramine (abbreviated as TETA 4+ ) organic cations. Under UV excitation, this hybrid organic-inorganic compound emits white light due to radiative recombinations of self-trapped excitons associated with a structural distortion of the PbBr 6 octahedra. Thin films of TETAPb 2 Br 8 show a photoluminescence (PL) quantum yield of ≈11% and exhibit a Commission Internationale de l'Eclairage coordinates of (0.32, 0.37). In the low-temperature range, the PL intensity increases with increasing temperature. This negative thermal quenching of white-light emission is interpreted in terms of transitions between excitonic states involving an exciton-phonon interaction. The interpretations are supported by the temperature dependence of the resonant Raman scattering and by density functional theory calculations.

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“…Definitely, much more reliable investigations were made for different first-principles calculations of specific crystals (see [209] as an example). Fairly good progress was achieved in first-principles calculation of activators, both rare earth ions (see [210] and [211]) and heavy ions [212], [213]. First-principle calculations make a step toward obtaining not only positions of energy levels, but some dynamical parameters, such as multiphonon capture and recombination rates [214]- [216], the parameters that are very important for reliable application of above-mentioned calculations using rate equations or kinetic Monte Carlo schemes.…”

Section: Theory and Modelingmentioning

confidence: 99%

Needs, Trends, and Advances in Inorganic Scintillators

Dujardin

Auffray

Bourret-Courchesne

et al. 2018

IEEE Trans. Nucl. Sci.

381

240

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This paper presents new developments in inorganic scintillators widely used for radiation detection. It addresses major emerging research topics outlining current needs for applications and material sciences issues with the overall aim to provide an up-to-date picture of the field. While the traditional forms of scintillators have been crystals and ceramics, new research on films, nanoparticles, and microstructured materials is discussed as these material forms can bring new functionality and therefore find applications in radiation detection. The last part of the contribution reports on the very recent evolutions of the most advanced theories, methods, and analyses to describe the scintillation mechanisms.

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Using DFT Methods to Study Activators in Optical Materials

Cited by 31 publications

References 113 publications

Bulk assembly of organic metal halide nanotubes

Bulk assembly of organic metal halide nanotubes

Negative Thermal Quenching of Efficient White‐Light Emission in a 1D Ladder‐Like Organic/Inorganic Hybrid Material

Needs, Trends, and Advances in Inorganic Scintillators

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