Photo‐Chemistry of Colloidal Metal Sulfides 8. Photo‐Physics of Extremely Small CdS Particles: Q‐State CdS and Magic Agglomeration Numbers

Fojtík, A.; Weller, Horst; Koch, Ueli; Henglein, A.

doi:10.1002/bbpc.19840881010

Cited by 348 publications

(148 citation statements)

References 16 publications

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“…27 Brus and co-workers suggested that sulfur vacancies, located at the surface of the material, might be important in mediating low-energy emissions. There are several reasons for this, one of which is the considerable size of 48. The excitonic transition shifts to higher energy values along with an increase in the molar absorption coefficient, as the particle size decrease.…”

Section: Theoretical Considerationsmentioning

confidence: 99%

Nanocrystalline Semiconductors: Synthesis, Properties, and Perspectives

2001

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The synthesis and study of so-called "nanoparticles", particles with diameters in the range of 1-20 nm, has become a major interdisciplinary area of research over the past 10 years. Semiconductor nanoparticles promise to play a major role in several new technologies. The intense interest in this area derives from their unique chemical and electronic properties, which gives rise to their potential use in the fields of nonlinear optics, luminescence, electronics, catalysis, solar energy conversion, and optoelectronics, as well as other areas. The small dimensions of these particles result in different physical properties from those observed in the corresponding macrocrystalline, "bulk", material. As particle sizes become smaller, the ratio of surface atoms to those in the interior increase, leading to the surface properties playing an important role in the properties of the material. Semiconductor nanoparticles also exhibit a change in their electronic properties relative to that of the bulk material; as the size of the solid becomes smaller, the band gap becomes larger. This allows chemists and material scientists the unique opportunity to change the electronic and chemical properties of a material simply by controlling its particle size. Research has already led to the fabrication of a number of devices. This review aims to highlight recent advances in the synthesis of compound semiconductor nanoparticle materials and their potential use in areas such as catalysis and electronic device fabrication.

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Section: Theoretical Considerationsmentioning

confidence: 99%

Nanocrystalline Semiconductors: Synthesis, Properties, and Perspectives

2001

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“…The idea that negatively charged nanoparticles can agglomerate to form larger particles via magic-number progression was proposed in ref. 4 , and in 1987 he explained the stability of polydisperse superspheres containing a few tens of nanoscale particles in terms of the balance between long-range electrostatic repulsion and short-range attractive dispersion forces 6 . In the early 1990s Zukoski and co-workers also explored how equilibrium between long-and short-range forces influenced the size of nanoparticle clusters 7,8 .…”

mentioning

confidence: 99%

Self-assembly of self-limiting monodisperse supraparticles from polydisperse nanoparticles

Xia¹,

Nguyen²,

Yang³

et al. 2012

Nature Nanotech

103

156

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“…[ 78 ] The conversion between radius and volume relied on the assumption that the clusters are approximately spherical. The absorption spectrum of a population of magic clusters formed in the absence of excess ligand was found to be composed -as in the system of Henglein and coworkers, [ 6 ] and others [ 76 , 79 , 80 ] -of multiples of a monomer cluster. Furthermore, the absorption from the larger clusters increased at the expense of the smaller clusters as the reaction progressed.…”

Section: Progress Reportmentioning

confidence: 94%

Nanowires and Nanostructures that Grow like Polymer Molecules

Shaw

Cademartiri

2013

Advanced Materials

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Unique properties (e.g., rubber elasticity, viscoelasticity, folding, reptation) determine the utility of polymer molecules and derive from their morphology (i.e., one-dimensional connectivity and large aspect ratios) and flexibility. Crystals do not display similar properties because they have smaller aspect ratios, they are rigid, and they are often too large and heavy to be colloidally stable. We argue, with the support of recent experimental studies, that these limitations are not fundamental and that they might be overcome by growth processes that mimic polymerization. Furthermore, we (i) discuss the similarities between crystallization and polymerization, (ii) critically review the existing experimental evidence of polymer-like growth kinetic and behavior in crystals and nanostructures, and (iii) propose heuristic guidelines for the synthesis of "polymer-like" crystals and assemblies. Understanding these anisotropic materials at the boundary between molecules and solids will determine whether we can confer the unique properties of polymer molecules to crystals, expanding them with topology, dynamics, and information and not just tuning them with size.

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Photo‐Chemistry of Colloidal Metal Sulfides 8. Photo‐Physics of Extremely Small CdS Particles: Q‐State CdS and Magic Agglomeration Numbers

Cited by 348 publications

References 16 publications

Nanocrystalline Semiconductors: Synthesis, Properties, and Perspectives

Nanocrystalline Semiconductors: Synthesis, Properties, and Perspectives

Self-assembly of self-limiting monodisperse supraparticles from polydisperse nanoparticles

Nanowires and Nanostructures that Grow like Polymer Molecules

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