Small Number of Defects per Nanostructure Leads to “Digital” Quenching of Photoluminescence: The Case of Metal Halide Perovskites

Ivan G. Scheblykin

doi:10.1002/aenm.202001724

Small Number of Defects per Nanostructure Leads to “Digital” Quenching of Photoluminescence: The Case of Metal Halide Perovskites

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Abstract

Long charge carrier diffusion length and large grain size are commonly believed to be inherent properties of highly luminescent polycrystalline thin-film semiconductors. However, exactly these two properties make luminescence very susceptible to quenching by just one strongly quenching defect state if present in each grain. Moreover, when the number of quenchers per grain is small (say 1–10), it varies greatly from grain to grain, purely for statistical reasons. These fluctuations, which resemble digital signal switching, can be one of the reasons for large differences between the luminescence brightness of different grains in polycrystalline films. This and other peculiarities of photoluminescence in systems where the number of strong quenchers per grain/crystallite is small is discussed in detail using metal halide perovskites as examples.

Original language	English
Article number	2001724
Journal	Advanced Energy Materials
Volume	10
Issue number	46
Early online date	2020 Oct 26
DOIs	https://doi.org/10.1002/aenm.202001724
Publication status	Published - 2020 Dec 8

Subject classification (UKÄ)

Condensed Matter Physics (including Material Physics, Nano Physics)
Physical Chemistry (including Surface- and Colloid Chemistry)

Free keywords

charge carrier diffusion
crystal size
nonradiative recombination
photoluminescence quenching
statistical inhomogeneity

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10.1002/aenm.202001724

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title = "Small Number of Defects per Nanostructure Leads to “Digital” Quenching of Photoluminescence: The Case of Metal Halide Perovskites",

abstract = "Long charge carrier diffusion length and large grain size are commonly believed to be inherent properties of highly luminescent polycrystalline thin-film semiconductors. However, exactly these two properties make luminescence very susceptible to quenching by just one strongly quenching defect state if present in each grain. Moreover, when the number of quenchers per grain is small (say 1–10), it varies greatly from grain to grain, purely for statistical reasons. These fluctuations, which resemble digital signal switching, can be one of the reasons for large differences between the luminescence brightness of different grains in polycrystalline films. This and other peculiarities of photoluminescence in systems where the number of strong quenchers per grain/crystallite is small is discussed in detail using metal halide perovskites as examples.",

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T1 - Small Number of Defects per Nanostructure Leads to “Digital” Quenching of Photoluminescence

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AU - Scheblykin, Ivan G.

PY - 2020/12/8

Y1 - 2020/12/8

N2 - Long charge carrier diffusion length and large grain size are commonly believed to be inherent properties of highly luminescent polycrystalline thin-film semiconductors. However, exactly these two properties make luminescence very susceptible to quenching by just one strongly quenching defect state if present in each grain. Moreover, when the number of quenchers per grain is small (say 1–10), it varies greatly from grain to grain, purely for statistical reasons. These fluctuations, which resemble digital signal switching, can be one of the reasons for large differences between the luminescence brightness of different grains in polycrystalline films. This and other peculiarities of photoluminescence in systems where the number of strong quenchers per grain/crystallite is small is discussed in detail using metal halide perovskites as examples.

AB - Long charge carrier diffusion length and large grain size are commonly believed to be inherent properties of highly luminescent polycrystalline thin-film semiconductors. However, exactly these two properties make luminescence very susceptible to quenching by just one strongly quenching defect state if present in each grain. Moreover, when the number of quenchers per grain is small (say 1–10), it varies greatly from grain to grain, purely for statistical reasons. These fluctuations, which resemble digital signal switching, can be one of the reasons for large differences between the luminescence brightness of different grains in polycrystalline films. This and other peculiarities of photoluminescence in systems where the number of strong quenchers per grain/crystallite is small is discussed in detail using metal halide perovskites as examples.

KW - charge carrier diffusion

KW - crystal size

KW - nonradiative recombination

KW - photoluminescence quenching

KW - statistical inhomogeneity

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U2 - 10.1002/aenm.202001724

DO - 10.1002/aenm.202001724

M3 - Article

AN - SCOPUS:85093984222

SN - 1614-6832

VL - 10

JO - Advanced Energy Materials

JF - Advanced Energy Materials

IS - 46

M1 - 2001724

ER -

Small Number of Defects per Nanostructure Leads to “Digital” Quenching of Photoluminescence: The Case of Metal Halide Perovskites

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