Energy Transfer in Stability-Optimized Perovskite Nanocrystals

Greiner, Michèle G; Singldinger, Andreas; Henke, Nina A; Lampe, Carola; Leo, Ulrich; Gramlich, Moritz; Urban, Alexander S.

doi:10.1021/acs.nanolett.2c02108

Cited by 18 publications

(11 citation statements)

References 32 publications

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“…We also observed an increase in the acceptor emission decay (Figure b). These observations can be accounted for by considering effective energy transfer from PNCs to RITC. − ,,, The kinetic parameters obtained upon triple-exponential fitting of all the PL decay profiles are summarized in Table S1. Among all five donor samples, the largest decrease in τ avg (∼58.3%) was seen for PNC-X1.…”

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confidence: 99%

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Energy Funneling from Water-Dispersed Perovskites to Chromophores

et al. 2023

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Cesium lead halide perovskite nanocrystals (PNCs) have enjoyed enormous attention in optoelectronics and photovoltaics. However, instability under polar conditions and limited energy/charge transport due to long-chain capping ligands restrict their large-scale applications. We have engineered a short-chain multidentate bolaamphiphilic ligand (NKE-3), which provides synergistic passivation of the perovskite surface by one multidentate ionic terminal and localizes water molecules by another multidentate ionic terminal, leading to a watersuspended colloidal solution of PNCs. NKE-3 allows efficient long-range dipole-based fluorescence resonance energy transfer (FRET) from perovskites to Rhodamine B isothiocyanate (RITC) in water, with FRET efficiencies ranging from 96% to 98%. We calculated the FRET rate using the acceptor's rise-time component, as it ensures no contamination from FRET-inactive donors. Moreover, we tuned the emission maxima of PNCs through halide exchange to optimize FRET efficiency. Such energy funneling to a suitable molecular photocatalyst is imperative for PNCs' potential applications.

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confidence: 99%

“…Fluorescence resonance energy transfer (FRET) is one such mechanism that describes the funneling of energy between two light-sensitive molecules . Therefore, employing PNCs in the fabrication of energy transfer assemblies might enable fine-grained regulation of energy flow. − …”

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Energy Funneling from Water-Dispersed Perovskites to Chromophores

et al. 2023

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“…We provided a rationale to explain such distance-dependent FRET by considering the flexible behavior of NKE and their electrostatic interactions with RITC. Unlike previous studies elucidating a trade-off between ϕ FRET and water stability, this work presents a promising approach to optimize the excitation energy funneling from PNCs with adequate water stability . Our results can aid in the advancements of PNCs in moisture-resistant photovoltaics, light-harvesting assemblies, and optoelectronics as well as expand the field of cascade energy/charge transfer-mediated photocatalysis.…”

Section: Introductionmentioning

confidence: 90%

Enhanced Stability and Energy Transfer in Perovskite Nanocrystals: Paving the Way for Moisture-Resistant Light-Harvesting Devices

Aggarwal,

Halder,

Neelakshi

et al. 2023

ACS Appl. Nano Mater.

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“…54,55 Moreover, macromolecule passivation, including polyimide, 56 polyacrylonitrile, 57 and polyfluorene suppressing the halide ion migration, 58 was found to be equally advantageous to enhancing PNC stability by suppressing the halide ion migration or forming coordination interaction for potential applications in CO 2 conversion, wide-color gamut displays, light-emitting diode (LED) devices, 59 and stretchable displays. 60,61 In addition to homopolymers, well-defined synthetic linear 61−64 and star-like block copolymers 65 with controlled molecular weight, pre-designed compositional architecture, and functionality were utilized to obtain highly stable PNCs owing to their ability to coordinate with surface atoms on PNCs to maintain colloidal stability, fill the traps to achieve the high PLQY, and form a condense protection shield on PNCs to maintain moisture stability. Apart from stability enhancing strategies via surface coating or surface ligand engineering, substitution of the A or B site element in the perovskite structure with dopants, 66,67 generation of a halide-rich surface, 68 and in situ formation in the natural product 69 were also proven to be effective for preserving perovskite phase stability and thermal stability without sacrificing the optical property, which were favorable to PNC-related devices requiring excellent charge-transport properties.…”

Section: ■ Introductionmentioning

confidence: 99%

“…by constructing inert shielding on the surface of PNCs to prevent the perovskite crystal structure from being damaged by external perturbations and preserve optical properties. Surface-capping ligand engineering based on small molecules (e.g., semiconducting molecule, metal complex, organic sulfonium bromide, inorganic metal salt, and zwitterionic molecule) was identified as another efficacious approach for strongly anchoring on the PNCs to repair the surface defects of PNCs, thereby addressing the ligand thermodynamic instability issue of originally capped oleylamine (OAm) or oleic acid (OA) while increasing the various stabilities of PNCs (even in water) with high PLQY. , Although the stability of PNCs synthesized from this approach may not be as high as that of PNCs fabricated from inorganic coating strategies because PNCs were not fully covered by insulating ligands, a reasonable balance was made between the structural stability and electron/hole transportation property, which was essential for the high-performance PNC-based optoelectronics. , Moreover, macromolecule passivation, including polyimide, polyacrylonitrile, and polyfluorene suppressing the halide ion migration, was found to be equally advantageous to enhancing PNC stability by suppressing the halide ion migration or forming coordination interaction for potential applications in CO 2 conversion, wide-color gamut displays, light-emitting diode (LED) devices, and stretchable displays. , In addition to homopolymers, well-defined synthetic linear − and star-like block copolymers with controlled molecular weight, pre-designed compositional architecture, and functionality were utilized to obtain highly stable PNCs owing to their ability to coordinate with surface atoms on PNCs to maintain colloidal stability, fill the traps to achieve the high PLQY, and form a condense protection shield on PNCs to maintain moisture stability. Apart from stability enhancing strategies via surface coating or surface ligand engineering, substitution of the A or B site element in the perovskite structure with dopants, , generation of a halide-rich surface, and in situ formation in the natural product were also proven to be effective for preserving perovskite phase stability and thermal stability without sacrificing the optical property, which were favorable to PNC-related devices requiring excellent charge-transport properties.…”

Section: Introductionmentioning

confidence: 99%

NondemandingIn SituEncapsulation Route to Ultrastable Perovskite Nanocrystals for White Light-Emitting Diodes

Wang

Zhang

et al. 2023

ACS Appl. Nano Mater.

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Although tremendous advancement regarding the highly stable metal halide perovskite nanocrystals (PNCs) has been achieved, previous studies were primarily focused on green light-emitting PNCs (i.e., bromine-based PNCs). The stability of chlorine-based PNCs with a violet or blue emission property was still lagging behind that of their bromine-based counterparts. Herein, a nondemanding and versatile strategy for in situ encapsulating allinorganic chlorine-based PNCs with multifold exceptionally high stabilities was presented. Wellordered mesoporous silica enabled the confined growth of PNCs in its pores followed by the porosity sealing by tetramethyl orthosilicate hydrolysis, thereby rendering full encapsulation of chlorine-based PNCs in dense silica that originated from high-temperature calcination. This judiciously designed structure imparted enclosed violet/blue emitting PNCs impart with outstanding long-term stability (>1.5 year) with high photoluminescence quantum yield (i.e., 30.4%) in pure water as the result of complete isolation of PNCs from detrimental stimuli, eventually leading to the application in the white light-emitting diode device.

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Energy Transfer in Stability-Optimized Perovskite Nanocrystals

Cited by 18 publications

References 32 publications

Energy Funneling from Water-Dispersed Perovskites to Chromophores

Energy Funneling from Water-Dispersed Perovskites to Chromophores

Enhanced Stability and Energy Transfer in Perovskite Nanocrystals: Paving the Way for Moisture-Resistant Light-Harvesting Devices

NondemandingIn SituEncapsulation Route to Ultrastable Perovskite Nanocrystals for White Light-Emitting Diodes

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