Morphogenesis of One‐Dimensional ZnO Nano‐ and Microcrystals

Yan, Haoquan; He, Rongrui; Pham, Johnny D.; Yang, Peidong

doi:10.1002/adma.200390091

Cited by 450 publications

(304 citation statements)

References 24 publications

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“…1d). Branched crystals of zinc oxide were originally discovered in smokes from zinc smelting plants and have been prepared and studied in CVD systems for several decades 47 . In colloidal systems, it is now possible to prepare ensembles of centrally branched tetrapod nanocrystals with a high degree of control over the branch length and diameter 48,49 .…”

Section: Kinetic Shape Controlmentioning

confidence: 99%

Colloidal nanocrystal synthesis and the organic–inorganic interface

Yin

Alivisatos

2004

Nature

3,092

2,730

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Colloidal nanocrystals are sometimes referred to as 'artificial atoms' because the density of their electronic states-which controls many physical properties-can be widely and easily tuned by adjusting composition, size and shape. The combination of strongly size-and shape-dependent physical properties and ease of fabrication and processing makes nanocrystals promising building blocks for materials with designed functions 1,2 . But the ability to control the uniformity of the size, shape, composition, crystal structure and surface properties of the nanocrystals is not only of technological interest: having access to defined nanoscale structures is essential to uncovering their intrinsic properties unaffected by sample inhomogeneity. Rigorous understanding of the properties of individual nanocrystals enables exploitation of collective properties of nanocrystal ensembles, making it possible to design and fabricate novel electronic, magnetic and photonic devices and other functional materials based on these nanostructures.Colloidal nanocrystals with a semiconductor as the inorganic material-so-called quantum dots-exhibit size tunable band gaps and luminescence energies due to the quantum size effect 3 . This has led to their use as fluorescent biological labels 4-6 , with colloidal quantum dots now widely employed as targeted fluorescent labels in biomedical research applications. Compared to the organic fluorophores that have been used as biological labels previously, quantum dots are extremely bright and do not photo-bleach, and they provide a readily accessible range of colors. Other applications that could benefit from the combination of low-cost processing with solid-state performance include the use of colloidal quantum dots and rods as possible alternatives to semiconductor polymers in light emitting diodes 7 , lasers 8 , and solar cells 9 . The scope for these applications has prompted intensive study of the synthesis of these materials to optimize colloidal semiconductor nanocrystal fabrication. As a result, many new concepts for controlling the size, shape, and connectivity or coupling of colloidal nanocrystals have been developed first for these materials, but a unified set of synthesis control concepts is now also applied to other classes of materials such as metals and metal oxides. These materials will extend the range of potential applications for colloidal nanocrystals to many other areas, including catalysis.Over the last decade chemists have come to appreciate that from the point of view of synthesis, colloidal inorganic nanocrystals can be viewed as a class of macromolecule, with preparative strategies that are similar in many ways to those employed with artificial organic polymers. For nanocrystals of one to one hundred nanometers diameter, it is possible to define the average and the dispersion of the diameter, as well as the aspect ratio; the degree of precision with which the desired structure is realized is similar to what is achieved with synthetic polymers, where the preparative means at o...

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Section: Kinetic Shape Controlmentioning

confidence: 99%

Colloidal nanocrystal synthesis and the organic–inorganic interface

Yin

Alivisatos

2004

Nature

3,092

2,730

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“…The development and investigation of ZnO nanostructures for optoelectronic applications is extensive and well-documented, showcasing a variety of morphologies achievable across a wide range of deposition techniques [1][2][3][4][5][6][7][8][9] . Of particular interest for device applications is the growth of ZnO nanorod arrays (NRAs) from low temperature, aqueous deposition techniques [10] which, over the past decade, has seen morphological improvements in alignment and uniformity through the introduction of precursor ZnO seed layers [11] , pH control of the growth environment [12,13] , additive incorporation [14] , as well as manipulation of growth variables including duration and temperature [15][16][17][18] .…”

Section: Introductionmentioning

confidence: 99%

ZnO Nanorod Arrays as Electron Injection Layers for Efficient Organic Light Emitting Diodes

Faria

Campbell

McLachlan

2015

Adv Funct Materials

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Nanostructured oxide arrays have received significant attention as charge injection and collection electrodes in numerous optoelectronic devices. Zinc oxide (ZnO) nanorods have received particular interest owing to the ease of fabrication using scalable, solution processes with a high degree of control of rod dimension and density. Here we implement vertical ZnO nanorods as electron injection layers in organic light emitting diodes (OLEDs) for display and lighting purposes. Implementing our nanorods into devices with an emissive polymer, poly(9,9-dioctyluorene-altbenzothiadiazole) (F8BT) and poly(9,9-di-n-octylfluorene-alt-N-(4-butylphenyl)dipheny-lamine) (TFB) as an electron blocking layer, brightness and efficiencies up to 8600 cd/m 2 and 1.66 cd/A were achieved. We highlight simple solution processing methodologies combined with post-deposition thermal processing to achieve complete wetting of the nanorod arrays with the emissive polymer. The introduction of TFB to minimize charge leakage and non-radiative exciton decay results in dramatic increases to device yields and provides an insight into the operating mechanism of these devices. We demonstrate the detected emission originates from within the polymer layers with no evidence of ZnO band-2 edge or defect emission. The work represents a significant development for the ongoing implementation of ZnO nanorod arrays into efficient light emitting devices.

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“…A number of nanometer and micrometer ZnO materials of varied geometries have been produced, e.g. nanowires, nanosprings, nanoneedles, nanowalls, coaxial cables, tubes, tetrapods and sheets [4][5][6][7][8][9][10][11][12][13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Growth mechanism and characterization of zinc oxide microcages

Fan

Scholz

Kolb

et al. 2004

Solid State Communications

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We report the growth mechanism and structural properties of micrometer sized ZnO cages which were synthesized directly from Zn vapor deposition and oxidation. The ZnO microcages exhibit a hexagonal or spherical shape with partly or completely open surfaces and hollow interiors. The growth process of the microcages includes the deposition of Zn polyhedral particles, top face breaking of the Zn particles and Zn sublimation, and subsequent reaction to ZnO. By controlling the various growth stages, we obtained information on the growth mechanism of the ZnO cages, which appears to be different from a mechanism reported previously. The chemical composition and crystalline structure were studied using energy dispersive X-ray spectroscopy and transmission electron microscopy, respectively. The room-temperature photoluminescence spectrum indicates a large quantity of oxygen-vacancy related defects within the wall of the ZnO cages. q

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Morphogenesis of One‐Dimensional ZnO Nano‐ and Microcrystals

Cited by 450 publications

References 24 publications

Colloidal nanocrystal synthesis and the organic–inorganic interface

Colloidal nanocrystal synthesis and the organic–inorganic interface

ZnO Nanorod Arrays as Electron Injection Layers for Efficient Organic Light Emitting Diodes

Growth mechanism and characterization of zinc oxide microcages

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