Photoluminescence Temperature Dependence, Dynamics, and Quantum Efficiencies in Mn<sup>2+</sup>-Doped CsPbCl<sub>3</sub> Perovskite Nanocrystals with Varied Dopant Concentration

Yuan, Xianglin; Ji, Sihang; Siena, Michael C. De; Fei, Liling; Zhao, Zhao; Wang, Yunjun; Li, Haibo; Zhao, Jianlong; Gamelin, Daniel R.

doi:10.1021/acs.chemmater.7b03311

Cited by 289 publications

(482 citation statements)

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“…In all cases, the actual Mn 2+ incorporation is lower than the synthetic Mn 2+ loading, which indicates that Ge 2+ is preferentially incorporated into the CsGeX 3 lattice. This is consistent with previous reports on Mn 2+ ‐doped CsPbX 3 nanocrystals, whose fast nucleation kinetics reduces Mn 2+ incorporation ,,,. Interestingly, the chemical yield systematically decreases with increasing synthetic Mn 2+ loading, likely because the parent CsMnX 3 compound is too soluble in water and thus fails to completely precipitate (see S.…”

Section: Resultssupporting

confidence: 91%

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Lead‐Free Semiconductors: Soft Chemistry, Dimensionality Control, and Manganese‐Doping of Germanium Halide Perovskites

et al. 2019

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Lead halide perovskites have drawn enormous interest due to their exceptional photovoltaic and optoelectronic properties. However, the heavy metal lead is harmful to humans and the environment resulting in a need for strategies to replace this toxic element. Herein, we report a facile aqueous synthesis of CsGeX3 (X=I, Br) perovskite nanocrystals with size control achieved by varying the concentration of a cysteammonium halide ligand. We observe a variety of morphologies including pyramidal, hexagonal, and spheroidal. CsGeX3 nanocrystals undergo a lattice expansion due to partial replacement of Cs+ with larger cysteNH3+ cations into their lattice. We successfully dope Mn2+ into the CsGeX3 lattice for the first time with incorporation of up to 29% in bulk and 16% in nano samples. XRD peak shifts and EPR hyperfine splitting strongly indicate that Mn2+ is doped into the lattice. Our results introduce a new member to the lead‐free halide perovskite family and set the fundamental stage for their use in optoelectronic devices.

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Section: Resultssupporting

confidence: 91%

“…Doping with up to 46% Mn 2+ is currently possible, leading to modified magnetic and optical properties . Mn 2+ ‐doping enhances stability, increases quantum yield to 60%, and results in long exciton lifetimes ,. These enhanced properties are useful for LEDs, and solar cell downconverters …”

Section: Introductionmentioning

confidence: 99%

Lead‐Free Semiconductors: Soft Chemistry, Dimensionality Control, and Manganese‐Doping of Germanium Halide Perovskites

et al. 2019

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“…[51][52][53][54] Park et al observed strong photon antibunching as well as blinking behavior ascribed to charge/discharge events triggered by photoionization in CsPbBr 3 and CsPbI 3 . [56] Both transition metals [35,57] and rare earth metals [34] have been doped into CsPbX 3 , achieving quantum yields greater than 60 % and 170 %, respectively. [55] Pan et al first demonstrated lanthanide doping into CsPbCl 3 , showing improved quantum yield and luminescence bands across the visible and even into the near-IR region.…”

Section: Introductionmentioning

confidence: 99%

Unveiling the Photo‐ and Thermal‐Stability of Cesium Lead Halide Perovskite Nanocrystals

et al. 2019

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Lead halide perovskites possess unique characteristics that are well-suited for optoelectronic and energy capture devices, however, concerns about their long-term stability remain. Limited stability is often linked to the methylammonium cation, and all-inorganic CsPbX 3 (X=Cl, Br, I) perovskite nanocrystals have been reported with improved stability. In this work, the photostability and thermal stability properties of CsPbX 3 (X=Cl, Br, I) nanocrystals were investigated by means of electron microscopy, X-ray diffraction, thermogravimetric analysis coupled with FTIR (TGA-FTIR), ensemble and single particle spectral characterization. CsPbBr 3 was found to be stable under 1-sun illumination for 16 h in ambient conditions, although single crystal luminescence analysis after illumination using a solar simulator indicates that the luminescence states are changing over time. CsPbBr 3 was also stable to heating to 250°C. Large CsPbI 3 crystals (34 � 5 nm) were shown to be the least stable composition under the same conditions as both XRD reflections and Raman bands diminish under irradiation; and with heating the γ (black) phase reverts to the nonluminescent δ phase. Smaller CsPbI 3 nanocrystals (14 � 2 nm) purified by a different washing strategy exhibited improved photostability with no evidence of crystal growth but were still thermally unstable. Both CsPbCl 3 and CsPbBr 3 show crystal growth under irradiation or heat, likely with a preferential orientation based on XRD patterns. TGA-FTIR revealed nanocrystal mass loss was only from liberation and subsequent degradation of surface ligands. Encapsulation or other protective strategies should be employed for long-term stability of these materials under conditions of high irradiance or temperature.[a] B.

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“…In this scenario, Mn 2+ doping is currently considered one of the leading strategies to modify the optical and magnetic functionalities of nanocrystals of various chalcogenide and oxide semiconductors . An interesting synergy between these materials chemistry features was proposed by Yuan et al., who synthesized a series of Mn 2+ ‐doped CsPbCl 3 nanocrystals using reaction temperature and precursor concentration to tune Mn 2+ content up to 14 % . The obtained nanocrystals showed Mn 2+ 4 T 1g → 6 A 1g d‐d luminescence within the optical gap coexisting with excitonic luminescence at the nanocrystals absorption edge, and quantum yields up to 62 % were observed for Mn 2+ concentrations of about 3 %.…”

Section: Caesium‐doped Perovskites In Emerging Technologiesmentioning

confidence: 99%

Caesium for Perovskite Solar Cells: An Overview

Bella

Renzi

Cavallo

et al. 2018

Chemistry A European J

141

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Perovskite solar cells have the potential to revolutionize the world of photovoltaics, and their efficiency close to 23 % on a lab-scale recently certified this novel technology as the one with the most rapidly raising performance per year in the whole story of solar cells. With the aim of improving stability, reproducibility and spectral properties of the devices, in the last three years the scientific community strongly focused on Cs-doping for hybrid (typically, organolead) perovskites. In parallel, to further contrast hygroscopicity and reach thermal stability, research has also been carried out to achieve the development of all-inorganic perovskites based on caesium, the performances of which are rapidly increasing. The potential of caesium is further strengthened when it is used as a modifying agent of charge-carrier layers in solar cells, but also for the preparation of perovskites with peculiar optoelectronic properties for unconventional applications (e.g., in LEDs, photodetectors, sensors, etc.). This Review offers a 360-degree overview on how caesium can strongly tune the properties and performance of perovskites and relative perovskite-based devices.

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Photoluminescence Temperature Dependence, Dynamics, and Quantum Efficiencies in Mn²⁺-Doped CsPbCl₃ Perovskite Nanocrystals with Varied Dopant Concentration

Cited by 289 publications

References 56 publications

Lead‐Free Semiconductors: Soft Chemistry, Dimensionality Control, and Manganese‐Doping of Germanium Halide Perovskites

Lead‐Free Semiconductors: Soft Chemistry, Dimensionality Control, and Manganese‐Doping of Germanium Halide Perovskites

Unveiling the Photo‐ and Thermal‐Stability of Cesium Lead Halide Perovskite Nanocrystals

Caesium for Perovskite Solar Cells: An Overview

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Photoluminescence Temperature Dependence, Dynamics, and Quantum Efficiencies in Mn2+-Doped CsPbCl3 Perovskite Nanocrystals with Varied Dopant Concentration

Cited by 289 publications

References 56 publications

Lead‐Free Semiconductors: Soft Chemistry, Dimensionality Control, and Manganese‐Doping of Germanium Halide Perovskites

Lead‐Free Semiconductors: Soft Chemistry, Dimensionality Control, and Manganese‐Doping of Germanium Halide Perovskites

Unveiling the Photo‐ and Thermal‐Stability of Cesium Lead Halide Perovskite Nanocrystals

Caesium for Perovskite Solar Cells: An Overview

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Photoluminescence Temperature Dependence, Dynamics, and Quantum Efficiencies in Mn²⁺-Doped CsPbCl₃ Perovskite Nanocrystals with Varied Dopant Concentration