Tuning the Colloidal Softness of CsPbBr<sub>3</sub> Nanocrystals for Homogeneous Superlattices

Levy, Shahar; Beer, O.; Veber, Noam; Monachon, Christian; Bekenstein, Yehonadav

doi:10.1021/acs.nanolett.3c02023

Cited by 2 publications

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“…Lead halide perovskites, and in particular CsPbBr 3 , show giant oscillator strength and photoluminescence lifetimes that are an order of magnitude shorter than typical semiconducting nanocrystals, promising for ultrafast scintillation and detection . Also, CsPbBr 3 nanocrystals have bright tunable narrow emission , and reach near-unity quantum yield without thick inorganic shelling, indicating defects tolerance, unlike traditional semiconducting nanocrystals . Unfortunately, these materials experience strong self-absorption due to their small Stokes shift, and recently our group published a report on how composition tuning in double perovskites allows regulating Stokes shift by moving absorption and/or emission bands .…”

Section: Enhancement Of Time Resolution By a Meta-scintillation Approachmentioning

confidence: 99%

Bright Innovations: Review of Next-Generation Advances in Scintillator Engineering

Singh,

Dosovitskiy,

Bekenstein

2024

ACS Nano

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This review focuses on modern scintillators, the heart of ionizing radiation detection with applications in medical diagnostics, homeland security, research, and other areas. The conventional method to improve their characteristics, such as light output and timing properties, consists of improving in material composition and doping, etc., which are intrinsic to the material. On the contrary, we review recent advancements in cutting-edge approaches to shape scintillator characteristics via photonic and metamaterial engineering, which are extrinsic and introduce controlled inhomogeneity in the scintillator’s surface or volume. The methods to be discussed include improved light out-coupling using photonic crystal (PhC) coating, dielectric architecture modification producing the Purcell effect, and meta-materials engineering based on energy sharing. These approaches help to break traditional bulk scintillators’ limitations, e.g., to deal with poor light extraction efficiency from the material due to a typically large refractive index mismatch or improve timing performance compared to bulk materials. In the Outlook section, modern physical phenomena are discussed and suggested as the basis for the next generations of scintillation-based detectors and technology, followed by a brief discussion on cost-effective fabrication techniques that could be scalable.

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Section: Enhancement Of Time Resolution By a Meta-scintillation Approachmentioning

confidence: 99%

Bright Innovations: Review of Next-Generation Advances in Scintillator Engineering

Singh,

Dosovitskiy,

Bekenstein

2024

ACS Nano

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Ferroelasticity in Halide Perovskites Affects Electro‐Optical Properties through Facet Stability

Veber,

Shamaev,

Shaek

et al. 2024

Advanced Optical Materials

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Advancements in ferroic materials center upon understanding domain structures and their boundaries. This study innovates by directing the growth of lead halide perovskite microcrystals from the gas phase onto pre‐chosen substrates, thereby inducing an interfacial strain that prompts ferroelasticity‐driven structural transformation. A method of ferroelastic engineering in vapor‐grown perovskite heterostructures is thus unveiled, revealing ordered domain patterns of bright crystals with contrasting electro‐optical properties. In the case of the frustrated halide perovskite crystals, the strain is relaxed by the formation of alternating crystallographic twin domains. In the demonstrated orthorhombic system, these domains alternate between (110) and (002) orientation, with a (112) domain boundary. Perovskite ferroelastic effect with facet stability is correlated, attributed to the exposure of lower surface energy terminations, promoting the material's stability and efficiency. This findings result from direct electrical measurements, which pave the way for the tailored design of ferroic materials, optimizing their optoelectronic characteristics for enhanced device performance.

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Tuning the Colloidal Softness of CsPbBr₃ Nanocrystals for Homogeneous Superlattices

Cited by 2 publications

References 38 publications

Bright Innovations: Review of Next-Generation Advances in Scintillator Engineering

Bright Innovations: Review of Next-Generation Advances in Scintillator Engineering

Ferroelasticity in Halide Perovskites Affects Electro‐Optical Properties through Facet Stability

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Tuning the Colloidal Softness of CsPbBr3 Nanocrystals for Homogeneous Superlattices

Cited by 2 publications

References 38 publications

Bright Innovations: Review of Next-Generation Advances in Scintillator Engineering

Bright Innovations: Review of Next-Generation Advances in Scintillator Engineering

Ferroelasticity in Halide Perovskites Affects Electro‐Optical Properties through Facet Stability

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Product

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Tuning the Colloidal Softness of CsPbBr₃ Nanocrystals for Homogeneous Superlattices