Luminescent Anisotropic Wurtzite InP Nanocrystals

Stone, David A.; Koley, Somnath; Remennik, Sergei; Asor, Lior; Panfil, Yossef E.; Naor, Tom; Banin, Uri

doi:10.1021/acs.nanolett.1c03719

Cited by 10 publications

(29 citation statements)

References 47 publications

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“…Synthesizing anisotropic morphologies such as nanorods and nanoplatelets traditionally requires an anisotropic crystal lattice. Stone et al recently produced fluorescent wurtzite InP QDs via cation exchange from hexagonal Cu 3 P nanocrystals . These spherical QDs contain <1% Cu after exchange and NOBF 4 treatment and display up to 40% PLQYs without shelling.…”

Section: Summary and Perspectivesmentioning

confidence: 99%

“…Stone et al recently produced fluorescent wurtzite InP QDs via cation exchange from hexagonal Cu 3 P nanocrystals. 141 These spherical QDs contain <1% Cu after exchange and NOBF 4 treatment and display up to 40% PLQYs without shelling. Expanding our library of InP QDs to anisotropic morphologies is essential to utilizing polarized light transitions for optoelectronic applications.…”

Section: Summary and Perspectivesmentioning

confidence: 99%

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Synthesis, Surface Chemistry, and Fluorescent Properties of InP Quantum Dots

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Rosenthal

2023

Chem. Mater.

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InP quantum dots (QDs) have great potential as emitters for solid-state lighting, lasing, and bioimaging without the inherent toxicity concern of Cd and Pb-based emitters. Indium phosphide's small bandgap and high covalency make it uniquely capable of color-pure fluorescence that can be tuned throughout the visible and lower IR spectrum. Until recently, InP-based QDs consistently underperformed when compared with CdSe-based counterparts. Recent efforts to understand indium phosphide's nonclassical growth mechanisms, control the nanocrystal shape, control in situ formation of surface oxides, and grow thick, uniform shells have produced InP-based QDs comparable to their CdSe competitors with >95% quantum yields (QYs) in red, green, and blue emission wavelengths. This review covers the most common synthetic techniques, the most recent theories on InP formation mechanisms, the current understanding of InP surface chemistries, and the breadth of fluorescent properties of InP-based QDs.

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Section: Summary and Perspectivesmentioning

confidence: 99%

Section: Summary and Perspectivesmentioning

confidence: 99%

Synthesis, Surface Chemistry, and Fluorescent Properties of InP Quantum Dots

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Rosenthal

2023

Chem. Mater.

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“…As a milder etchant, NOBF 4 removes the native insulating ligands, as well as the surface oxide or side products, thereby enhancing the film conductivity 56 or emission properties, as shown in Figure 3a. 57 Ligand manipulation approaches for group III−V CQDs passivation are still in the very early stage, mainly because of the limited atomistic understanding of surface structures. Recently, it has been suggested that Z-type ligands can effectively passivate the deep traps from two-coordinated anions on the group III−V surfaces.…”

Section: ■ Group Iii−v Cqd Surface and Modificationsmentioning

confidence: 99%

“…Moreover, oxides or impurities formed on the surface of CQDs can be etched off. As a milder etchant, NOBF 4 removes the native insulating ligands, as well as the surface oxide or side products, thereby enhancing the film conductivity or emission properties, as shown in Figure a …”

Section: Group Iii–v Cqd Surface and Modificationsmentioning

confidence: 99%

Development of Group III–V Colloidal Quantum Dots for Optoelectronic Applications

et al. 2022

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Colloidal quantum dots (CQDs) are freestanding, confinement-based energy-band-tunable materials that enable the formation of thin-film device structures for various optoelectronic applications. Group III−V CQDs (InP, InAs, and InSb) without toxic elements such as Cd, Pb, and Hg are currently being extensively explored, as the covalent crystal nature in bonding can provide robustness toward external stresses. Despite successful implementation in specific areas, such as CQD-based light downconversion optoelectronics, most state-of-the-art group III−V CQD-based devices still suffer from low efficiency compared to other CQD-based devices. In this Focus Review, we address the challenges specific to efficient group III−V CQD-based optoelectronics design and fabrication and highlight recent approaches for overcoming these challenges, in view of synthesis, surface modification, and effective carrier modulation. Finally, we discuss the perspectives and outlook for achieving efficient group III−V CQD optoelectronics.

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“…Therefore, InAs NCs with anisotropic wurtzite phase can potentially emit photons with desired polarization direction upon proper band structure engineering, which is highly appealing for light extraction applications in optoelectronic display devices. Additionally, the chemical reactivity difference among various facets of wurtzite NCs enables the synthesis of anisotropic heterostructured NCs, such as asymmetric quantum dots, dot-in-rod NCs, and dot-in-plate NCs, which display unique optical properties. − However, colloidal InAs NCs directly produced through molecular precursors unanimously exhibited symmetric zinc-blende crystal structure. − Successful synthesis of metastable wurtzite InAs NCs has never been achieved, presumably due to the relatively large energy difference (∼6.28 meV/atom) between the zinc-blende and wurtzite InAs polytypes …”

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confidence: 99%

Wurtzite InAs Nanocrystals with Short-Wavelength Infrared Emission Synthesized through the Cation Exchange of Cu₃As Nanocrystals

Shan

Zhou

et al. 2023

Chem. Mater.

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Colloidal InAs nanocrystals (NCs) are among the most promising light emitters in the short-wavelength infrared (SWIR) range. These InAs NCs are eligible to crystalize into two distinct phases, i.e., cubic zinc-blende phase and metastable hexagonal wurtzite phase. However, InAs NCs directly produced through molecular precursors unanimously exhibited zinc-blende structure, and the synthesis of their wurtzite counterparts has never been achieved. Herein, we report the first successful synthesis of high-quality wurtzite InAs NCs, which show bright SWIR photoluminescence with a tunable emission peak and high quantum yield of up to ∼37%. This is achieved by the cation exchange of Cu3As NCs with controllable size and morphology, followed by the growth of inorganic passivation layers to eliminate the possible surface trap centers. We further expand the synthesis route to wurtzite ternary InAs0.5P0.5 NCs with quasi-one dimensional confinement, which exhibit polarized SWIR emission, exploring the potential of these anisotropic NCs as efficient polarized light emitters.

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Luminescent Anisotropic Wurtzite InP Nanocrystals

Cited by 10 publications

References 47 publications

Synthesis, Surface Chemistry, and Fluorescent Properties of InP Quantum Dots

Synthesis, Surface Chemistry, and Fluorescent Properties of InP Quantum Dots

Development of Group III–V Colloidal Quantum Dots for Optoelectronic Applications

Wurtzite InAs Nanocrystals with Short-Wavelength Infrared Emission Synthesized through the Cation Exchange of Cu₃As Nanocrystals

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Luminescent Anisotropic Wurtzite InP Nanocrystals

Cited by 10 publications

References 47 publications

Synthesis, Surface Chemistry, and Fluorescent Properties of InP Quantum Dots

Synthesis, Surface Chemistry, and Fluorescent Properties of InP Quantum Dots

Development of Group III–V Colloidal Quantum Dots for Optoelectronic Applications

Wurtzite InAs Nanocrystals with Short-Wavelength Infrared Emission Synthesized through the Cation Exchange of Cu3As Nanocrystals

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Wurtzite InAs Nanocrystals with Short-Wavelength Infrared Emission Synthesized through the Cation Exchange of Cu₃As Nanocrystals