2017
DOI: 10.1021/acs.jpcc.7b06301
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Temperature-Dependent Photoluminescence of Cesium Lead Halide Perovskite Quantum Dots: Splitting of the Photoluminescence Peaks of CsPbBr3 and CsPb(Br/I)3 Quantum Dots at Low Temperature

Abstract: We investigated the temperature-dependent photoluminescence (PL) properties of colloidal CsPbX 3 (X = Br, I, and mixed Br/I) quantum dot (QD) samples in the 30−290 K temperature range. Temperature-dependent PL experiments reveal thermal quenching of PL, blue shifting of optical band gaps, and line width broadening for all CsPbX 3 QD samples with increasing temperature. Interestingly, side-peak emissions that are spectrally separated from the excitonic PL peaks were observed for both CsPbBr 3 and CsPb(Br/I) 3 Q… Show more

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Cited by 141 publications
(130 citation statements)
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“…The line shape can be well reproduced by a best fit with two Gaussian bands peaked at 2.3873 and 2.405 eV and with a FWHM of 149 and 50 meV, respectively. Similar spectra have been reported in the literature for CsPbBr 3 NCs films, ascribing the broad band at low energy to excitons bound to defects (BE) and the narrow band at higher energy to free excitons (FE) [30,31] The PL intensity presents a quite stable value during continuous laser irradiation (see Figure 3a) with signal variation within 3% around the average values. When the sample atmosphere is changed from V to WA, we observe (see inset of Figures 2a and 3a) an intensity increase by a factor 1.3 (about 30%), and the signal attests itself to the new value within the WA recovering time (less than 5 s).…”
Section: Resultssupporting
confidence: 85%
“…The line shape can be well reproduced by a best fit with two Gaussian bands peaked at 2.3873 and 2.405 eV and with a FWHM of 149 and 50 meV, respectively. Similar spectra have been reported in the literature for CsPbBr 3 NCs films, ascribing the broad band at low energy to excitons bound to defects (BE) and the narrow band at higher energy to free excitons (FE) [30,31] The PL intensity presents a quite stable value during continuous laser irradiation (see Figure 3a) with signal variation within 3% around the average values. When the sample atmosphere is changed from V to WA, we observe (see inset of Figures 2a and 3a) an intensity increase by a factor 1.3 (about 30%), and the signal attests itself to the new value within the WA recovering time (less than 5 s).…”
Section: Resultssupporting
confidence: 85%
“…Unlike single crystals, NCs may show an inhomogeneous linewidth due to variable environments (frequently observed as spectral diffusion in single particle measurements) and size dispersion, arising from quantum confinement effects, although these are expected to be weak for the NCs measured here . We do not observe any clear secondary features or shoulder of the PL at any temperature, despite earlier reports . Thermal broadening of PL at higher temperatures, plotted in Figure b, is accounted for using a Voight fit.…”
Section: Resultscontrasting
confidence: 49%
“…E B signifies the exciton binding energy for excitons to obliterate by the non‐radiative trap states, in which the larger value is favourable for excitonic stabilization and for proficient PL. The value E B of Cs 3 Bi 2 I 6 Cl 3 NCs is estimated to be 69.90 meV from the linear plot of ln ( I 0 / I T ) and 1/ k B T (Figure S7b, SI), which is comparable with the earlier reported MA 3 Bi 2 I 9 (MA=methylammonium), but larger than that of the 3D CsPbX 3 NCs (≈15–50 meV) . The E B value of ≈70 meV is found to be higher than that of thermal ionization energy (≈26 meV), which confirmed the existence of excitons well above the room temperature, and further emphasized the prospective use of this material in exciton‐associated optoelectronic devices …”
Section: Resultssupporting
confidence: 84%