Shape control of CdSe nanocrystals

Peng, Xiaogang; Manna, Liberato; Yang, Weidong; Wickham, Juanita; Scher, Erik C.; Kadavanich, A. V.; Alivisatos, A. Paul

doi:10.1038/35003535

Cited by 4,306 publications

(3,539 citation statements)

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“…Besides using size to control their optical and electronic properties, SCNCs can be synthesized in a variety of shapes and dimensionalities (see below);17, 18, 19, 20, 21, 22 these characteristics govern the polarization and the directionality of the emission of the NCs. The surface of the NCs is easily processed, and hence NCs can be introduced onto various phases/substrates such as hydrophobic or hydrophilic media, and onto or into flexible or rigid substrates 23, 24, 25, 26.…”

Section: Introductionmentioning

confidence: 99%

Colloidal Quantum Nanostructures: Emerging Materials for Display Applications

2018

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Colloidal semiconductor nanocrystals (SCNCs) or, more broadly, colloidal quantum nanostructures constitute outstanding model systems for investigating size and dimensionality effects. Their nanoscale dimensions lead to quantum confinement effects that enable tuning of their optical and electronic properties. Thus, emission color control with narrow photoluminescence spectra, wide absorbance spectra, and outstanding photostability, combined with their chemical processability through control of their surface chemistry leads to the emergence of SCNCs as outstanding materials for present and next‐generation displays. In this Review, we present the fundamental chemical and physical properties of SCNCs, followed by a description of the advantages of different colloidal quantum nanostructures for display applications. The open challenges with respect to their optical activity are addressed. Both photoluminescent and electroluminescent display scenarios utilizing SCNCs are described.

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Section: Introductionmentioning

confidence: 99%

Colloidal Quantum Nanostructures: Emerging Materials for Display Applications

2018

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“…18 Nearly spherical to rod-like shapes are produced using ligands such as hexyl phosphonic acid. 19 Aspect ratio is sensitive to phosphonic acid alkyl chain length; the shorter the chain, the more elongated and branched are the nanorods. 18,20 Aspect ratio control has been studied for ZnS, ZnSe,16,21 ABSTRACT We demonstrate molecular control of nanoscale composition, alloying, and morphology…”

Section: Introductionmentioning

confidence: 99%

Molecular Control of the Nanoscale: Effect of Phosphine–Chalcogenide Reactivity on CdS–CdSe Nanocrystal Composition and Morphology

et al. 2012

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We demonstrate molecular control of nanoscale composition, alloying, and morphology (aspect ratio) in CdS-CdSe nanocrystal dots and rods by modulating the chemical reactivity of phosphine-chalcogenide precursors. Specific molecular precursors studied were sulfides and selenides of triphenylphosphite (TPP), diphenylpropylphosphine (DPP), tributylphosphine (TBP), trioctylphosphine (TOP), and hexaethylphosphorustriamide (HPT). Computational (DFT), NMR ( 31 P and 77 Se), and high-temperature crossover studies unambiguously confirm a chemical bonding interaction between phosphorus and chalcogen atoms in all precursors. Phosphine-chalcogenide precursor reactivity increases in the order: TPPE < DPPE < TBPE < TOPE 1-x Se x quantum dots were synthesized via single injection of a R 3 PS-R 3 PSe mixture to cadmium oleate at 250 degree C. X-ray diffraction (XRD), transmission electron microscopy (TEM), and UV/Vis and PL optical spectroscopy reveal that relative R 3 PS and R 3 PSe reactivity dictates CdS 1 -xSe x dot chalcogen content and the extent of radial alloying (alloys vs core/shells). CdS, CdSe, and CdS 1 -x Se x quantum rods were synthesized by injection of a single R 3 PE (E = S or Se) precursor or a R 3 PS-R 3 PSe mixture to cadmium-phosphonate at 320 or 250 degree C. XRD and TEM reveal that the length-to-diameter aspect ratio of CdS and CdSe nanorods is inversely proportional to R 3PE precursor reactivity. Purposely matching or mismatching R 3 PS-R 3 PSe precursor reactivity leads to CdS 1 -x Se x nanorods without or with axial composition gradients, respectively. We expect these observations will lead to scalable and highly predictable "bottom-up" programmed syntheses of finely heterostructured nanomaterials with well-defined architectures and properties that are tailored for precise applications. P reparative nanotechnology or "nanomanufacturing" is rapidly evolving toward fabrication of ever more complex materials with precise structure and properties. Tuning composition, relative configuration, and spatial arrangement of heterostructured nanomaterials can impact our ability to engineer and direct energy flows at the nanoscale. In the case of II 3 VI and IV 3 VI semiconductors, composition control has been demonstrated for homogeneously alloyed CdS 1Àx Se x , 1À4 CdS 1Àx Te x , 5 CdSe 1Àx Te x , 6 PbS x Se 1Àx , PbS x Te 1Àx , and PbSe x Te 1Àx 7 nanocrystals with size-and composition-tunable band gaps. 4,8,9 In some cases, a nonlinear relationship between composition and absorption/emission energies, called optical bowing, resulted in new properties not obtainable from the parent binary systems. 3 For example, CdS x Te 1Àx nanocrystals displayed small absorptionÀ emission spectral overlap, up to 150 nm Stokes shifts, and significantly red-shifted PL with respect to CdS and CdTe nanocrystals. 5 Controlling nanocrystal morphology is key to controlling nanocrystal properties. 10À14 A common technique to produce nanorods, for example, is to perform slow and/or subsequent reactant injections. 15À17 In i...

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“…Actually, controlled synthesis of nanostructured materials has been achieved by many solution-based methods [40 45]. For example, Peng et al demonstrated that control of the growth kinetics of the II IV semiconductor CdSe via adjusting monomer concentration could be used to vary the shapes of the resulting particles from a nearly spherical morphology to a rodlike one, with aspect ratios as large as ten to one [46]; the O'Brien group synthesized monodisperse MnO nanocrystals by thermal decomposition of manganese acetate in the presence of oleic acid at 320 °C and showed that the particle size could be adjusted from 12 to 20 nm by controlling the aging time [47]; Hyeon and co-workers also reported a one nanometer-level diameter-controlled synthesis of monodisperse magnetic iron oxide nanocrystals obtained by seed-mediated growth of previously synthesized monodisperse nanoparticle seeds [48]. Although these exciting results provide effective strategies for the synthesis of nanocrystals with controllable shape and size, what is still required is much more rational control over the nanocrystals, namely, the ability to design and optimize nanostructures at will.…”

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confidence: 99%