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Semiconductor quantum dots

Chattopadhyay PK, Price DA, Harper TF, Betts MR, Yu J, Gostick E, Perfetto SP, Goepfert P, Koup RA, De Rosa SC, Bruchez MP, Roederer M. Quantum dot semiconductor nanocrystals for immunophenotypmg by polychromatic flow cytometry. Nat Med 2006 12 972-977. [Pg.156]

Keywords Biomedical applications Electionic applications Environmental applications Polymer nanocomposites Quantum dots Semiconductor nanoparticles... [Pg.284]

After initial testing on small systems, Chelikowsky s group extended their real-space code (now called PARSEC) for a wide range of challenging applications.The applications include quantum dots, semiconductors, nanowires, spin polarization, and molecular dynamics to determine photoelectron spectra, metal clusters, and time-dependent DFT (TDDFT) calculations for excited-state properties. PARSEC calculations have been performed on systems with more than 10,000 atoms. The PARSEC code does not utilize MG methods but rather employs Chebyshev-filtered subspace acceleration and other efficient techniques during the iterative solution process. When possible, symmetries may be exploited to reduce the numbers of atoms treated explicitly. [Pg.256]

Llabres i Xamena EX, Corma A, Garcia H. Applications for metal-organic frameworks (mofs) as quantum dot semiconductors. J Phys Chem 2007 111 80-5. [Pg.109]

Brus L E 1993 NATO ASI School on Nanophase Materials ed G C Had]lpanayls (Dordrecht Kluwer) Allvisatos A P 1996 Semiconductor clusters, nanocrystals and quantum dots Science 271 933 Heath J R and Shlang J J 1998 Covalency In semiconductor quantum dots Chem. See. Rev. 27 65 Brus L 1998 Chemical approaches to semiconductor nanocrystals J. Phys. Chem. Solids 59 459 Brus L 1991 Quantum crystallites and nonlinear optics App/. Phys. A 53 465... [Pg.2921]

Bawendl M G, Stelgerwald M L and Brus L E 1990 The quantum mechanics of larger semiconductor clusters ( quantum dots ) Ann. Rev. Phys. Chem. 41 477... [Pg.2921]

Nanoclusters/Polymer Composites. The principle for developing a new class of photoconductive materials, consisting of charge-transporting polymers such as PVK doped with semiconductor nanoclusters, sometimes called nanoparticles, Q-particles, or quantum dots, has been demonstrated (26,27). [Pg.410]

Band gap engineetring confined hetetrostruciutres. When the thickness of a crystalline film is comparable with the de Broglie wavelength, the conduction and valence bands will break into subbands and as the thickness increases, the Fermi energy of the electrons oscillates. This leads to the so-called quantum size effects, which had been precociously predicted in Russia by Lifshitz and Kosevich (1953). A piece of semiconductor which is very small in one, two or three dimensions - a confined structure - is called a quantum well, quantum wire or quantum dot, respectively, and much fundamental physics research has been devoted to these in the last two decades. However, the world of MSE only became involved when several quantum wells were combined into what is now termed a heterostructure. [Pg.265]

Figure 7.5. Quantum-dot vertical-cavity surface-emitting semiconductor laser, svith an active layer consisting of self-assembled InojiGaAso s quantum dots (Fasor 1997),... Figure 7.5. Quantum-dot vertical-cavity surface-emitting semiconductor laser, svith an active layer consisting of self-assembled InojiGaAso s quantum dots (Fasor 1997),...
Alivisatos, A. P. (1996). Semiconductor clusters, nanocrystals, and quantum dots. Science, 271 933-937. [Pg.180]

Moreover, the possibility of considering single-electron phenomena in a frame of a dot-based system theory allows consideration of even semiconductor nanoparticles as quantum dots, useful for single-electron junctions (Averin et al. 1991). [Pg.174]

Thin film coatings of nanocrystalline semiconductors, as collections of quantum dots (QD or Q-dot) attached to a solid surface, resemble in many ways semiconductor colloids dispersed in a liquid or solid phase and can be considered as a subsection of the latter category. The first 3D quantum size effect, on small Agl and CdS colloids, was observed and correctly explained, back in 1967 [109]. However, systematic studies in this field only began in the 1980s. [Pg.182]

A novel, electrochemically assisted method of obtaining semiconductor quantum dots supported on a surface has been introduced by Penner and his group [123], It comprised a hybrid electrochemical/chemical (E/C) process consisting of electrochemical deposition followed by chemical modification and it was described as a general, rapid, and low-cost solution-phase method for synthesizing supported Q-dots of metal salts. [Pg.186]

Chemical and electrochemical techniques have been applied for the dimensionally controlled fabrication of a wide variety of materials, such as metals, semiconductors, and conductive polymers, within glass, oxide, and polymer matrices (e.g., [135-137]). Topologically complex structures like zeolites have been used also as 3D matrices [138, 139]. Quantum dots/wires of metals and semiconductors can be grown electrochemically in matrices bound on an electrode surface or being modified electrodes themselves. In these processes, the chemical stability of the template in the working environment, its electronic properties, the uniformity and minimal diameter of the pores, and the pore density are critical factors. Typical templates used in electrochemical synthesis are as follows ... [Pg.189]

Golan Y, Ter-Ovanesyan E, Manassen Y, Margulis L, Hodes G, Rubinstein I, BitheU EG, Hutchison JL (1996) Electrodeposited quantum dots IV. Epitaxial short-range order in amorphous semiconductor nanostructures. Surf Sci 350 277-284... [Pg.204]

Hodes G, Rubinstein I (2001) Electrodeposition of semiconductor quantum dot films. In Hodes G (ed) Electrochemistry of Nanostructures, Wiley-VCH, Weinheim... [Pg.204]

Nozik AJ (2008) Multiple exciton generation in semiconductor quantum dots. Chem Phys Lett 457 3-11... [Pg.307]

Particularly attractive for numerous bioanalytical applications are colloidal metal (e.g., gold) and semiconductor quantum dot nanoparticles. The conductivity and catalytic properties of such systems have been employed for developing electrochemical gas sensors, electrochemical sensors based on molecular- or polymer-functionalized nanoparticle sensing interfaces, and for the construction of different biosensors including enzyme-based electrodes, immunosensors, and DNA sensors. Advances in the application of molecular and biomolecular functionalized metal, semiconductor, and magnetic particles for electroanalytical and bio-electroanalytical applications have been reviewed by Katz et al. [142]. [Pg.340]

Trindade, T. (2002) Synthetic studies on 11/ VI semiconductor quantum dots. Curr. Opin. Solid State Mater. Sci., 6, 347-353. [Pg.167]

Tang, J. and Marcus, R. A. (2005) Diffusion-controlled electron transfer processes and power-law statistics of fluorescence intermittency of nanoparticles. Phys. Rev. Lett, 95, 107401-1-107401-4 Tang, J. and Marcus, R. A. (2005) Mechanisms of fluorescence blinking in semiconductor nanocrystal quantum dots./. Chem. Phys., 123,054704-1-054704-12. [Pg.169]


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See also in sourсe #XX -- [ Pg.361 ]




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Atomic Model of Semiconductor Quantum Dots

Energy Levels of a (Semiconductor) Quantum Dot

Quantum dot

Quantum dots doped semiconductor nanocrystals

Quantum semiconductors

Self-Formation of Semiconductor Quantum Dots

Semiconductor Quantum Dots for Analytical and Bioanalytical Applications

Semiconductor nanocrystals quantum dots

Semiconductor quantum dots Subject

Semiconductor quantum dots charge carriers

Semiconductor quantum dots dynamics

Semiconductor quantum dots electron-phonon

Semiconductor quantum dots incorporation

Semiconductor quantum dots luminescence

Semiconductor quantum dots multiple exciton

Semiconductor quantum dots relaxation

Semiconductor-biomolecule quantum dots

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