Slow Hot‐Carrier Cooling in Halide Perovskites: Prospects for Hot‐Carrier Solar Cells

Li, Mingjie; Fu, Jianhui; Xu, Qiang; Sum, Tze Chien

doi:10.1002/adma.201802486

Cited by 219 publications

(340 citation statements)

References 137 publications

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“…2(c) and 2(d)]. The carrier cooling times of the 2D NPs were comparable to the relevant values for many materials used for solar cells [16], including CH 3 NH 3 PbI 3 films [17] and CdS microplates [18]. The slow hot carrier cooling in 2D NPs indicates their small energy loss in optoelectronic device applications [16].…”

supporting

confidence: 56%

Giant two- to five-photon absorption in CsPbBr₂₇I₀₃ two-dimensional nanoplatelets

Zhao

Xiao

et al. 2019

Opt. Lett.

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CsPbBr 2.7 I 0.3 two-dimensional (2D) nanoplatelets (NPs) with emission wavelengths of 469 nm and 527 nm were synthesized and characterized. Femtosecond transient absorption spectra revealed hot carrier cooling times of ∼368 fs and ∼438 fs for 469 nm and 527 nm 2D NPs, respectively. Importantly, the 2D NPs exhibit giant two-, three-, four-, and five-photon absorption cross-sections, reaching ∼4.1 × 10 6 GM at 830 nm, ∼2.3 × 10 −74 cm 6 s 2 photon −2 at 1300 nm, 2.06 × 10 −104 cm 8 s 3 photon −3 at 1600 nm, and 1.50 × 10 −136 cm 10 s 4 photon −4 at 2200 nm, respectively, which are 3-8 orders of magnitude larger, compared to specially designed organic molecules.

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supporting

confidence: 56%

Giant two- to five-photon absorption in CsPbBr₂₇I₀₃ two-dimensional nanoplatelets

Zhao

Xiao

et al. 2019

Opt. Lett.

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“…In semiconductor QDs, such cooling rates, which are due to the coupling with lattice vibrations, are observed in early picoseconds, which is faster than the emission rates by approximately three orders of magnitude. Meanwhile, for special cases of QDs [299] and halide, perovskites [300] were described for which the electron carrier cooling was greatly retarded. In these cases, a slower carrier cooling was achieved when the spacing among their discrete electronic levels was much larger than the phonon energy.…”

Section: Optical Anisotropy and Macrodipolesmentioning

confidence: 99%

Excitons in Carbonic Nanostructures

Demchenko

2019

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Unexpectedly bright photoluminescence emission can be observed in materials incorporating inorganic carbon when their size is reduced from macro–micro to nano. At present, there is no consensus in its understanding, and many suggested explanations are not consistent with the broad range of experimental data. In this Review, I discuss the possible role of collective excitations (excitons) generated by resonance electronic interactions among the chromophore elements within these nanoparticles. The Förster-type resonance energy transfer (FRET) mechanism of energy migration within nanoparticles operates when the composing fluorophores are the localized electronic systems interacting at a distance. Meanwhile, the resonance interactions among closely located fluorophores may lead to delocalization of the excited states over many molecules resulting in Frenkel excitons. The H-aggregate-type quantum coherence originating from strong coupling among the transition dipoles of adjacent chromophores in a co-facial stacking arrangement and exciton transport to emissive traps are the basis of the presented model. It can explain most of the hitherto known experimental observations and must stimulate the progress towards their versatile applications.

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“…This mechanism is an alternative to the Rashba effect, which was proposed to lead to an inversion of dark and bright exciton states in CQDs [22]. Further, the potential of perovskite CQDs for hot-carriers solar cell applications has also been stressed [23]: the suppression of the LO relaxation process to longitudinal acoustic (LA) phonons was attributed to an optical phonon bottleneck effect [24], and later on related to the anharmonicity of the acoustic modes [25]. Then, a direct measurement of optical phonons branches with the same methodology as for the acoustic modes [18,19] becomes a necessary step to completely uncover carrier-phonon coupling dynamics and to assess the fundamental intrinsic limit of the mobility of charge carriers in these materials.…”

Section: Introductionmentioning

confidence: 99%

Direct evidence of weakly dispersed and strongly anharmonic optical phonons in hybrid perovskites

et al. 2020

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Hybrid organolead perovskites (HOP) have started to establish themselves in the field of photovoltaics, mainly due to their great optoelectronic properties and steadily improving solar cell efficiency. Study of the lattice dynamics is key in understanding the electron-phonon interactions at play, responsible for such properties. Here, we investigate, via neutron and Raman spectroscopies, the optical phonon spectrum of four different HOP single crystals: MAPbBr3, FAPbBr3, MAPbI3, and α-FAPbI3. Low temperature spectra reveal weakly dispersive optical phonons, at energies as low as 2-5 meV, which seem to be the origin of the limit of the charge carriers mobilities in these materials. The temperature dependence of our neutron spectra shows as well a significant anharmonic behaviour, resulting in optical phonon overdamping at temperatures as low as 80 K, questionning the validity of the quasi-particle picture for the low energy optical modes at room temperature where the solar cells operate.

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Slow Hot‐Carrier Cooling in Halide Perovskites: Prospects for Hot‐Carrier Solar Cells

Cited by 219 publications

References 137 publications

Giant two- to five-photon absorption in CsPbBr₂₇I₀₃ two-dimensional nanoplatelets

Giant two- to five-photon absorption in CsPbBr₂₇I₀₃ two-dimensional nanoplatelets

Excitons in Carbonic Nanostructures

Direct evidence of weakly dispersed and strongly anharmonic optical phonons in hybrid perovskites

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Slow Hot‐Carrier Cooling in Halide Perovskites: Prospects for Hot‐Carrier Solar Cells

Cited by 219 publications

References 137 publications

Giant two- to five-photon absorption in CsPbBr27I03 two-dimensional nanoplatelets

Giant two- to five-photon absorption in CsPbBr27I03 two-dimensional nanoplatelets

Excitons in Carbonic Nanostructures

Direct evidence of weakly dispersed and strongly anharmonic optical phonons in hybrid perovskites

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Product

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Giant two- to five-photon absorption in CsPbBr₂₇I₀₃ two-dimensional nanoplatelets

Giant two- to five-photon absorption in CsPbBr₂₇I₀₃ two-dimensional nanoplatelets