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%% Created for Dan Gezelter at 2007-09-06 16:43:33 -0400 |
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%% Created for Charles Vardeman at 2007-09-10 16:34:07 -0400 |
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%% Saved with string encoding Western (ASCII) |
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@unpublished{hartlandPrv2007, |
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Author = {G. V. Hartland}, |
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Date-Added = {2007-09-10 16:28:58 -0400}, |
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Date-Modified = {2007-09-10 16:34:05 -0400}, |
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Howpublished = {(private communication)}, |
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Note = {Private Communication}, |
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Title = {Interfacial Conductance for Nanoparticles}} |
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@article{xuan:043507, |
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Author = {Yimin Xuan and Qiang Li and Xing Zhang and Motoo Fujii}, |
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Date-Added = {2007-09-10 16:25:23 -0400}, |
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Date-Modified = {2007-09-10 16:26:01 -0400}, |
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Doi = {10.1063/1.2245203}, |
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Eid = {043507}, |
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Journal = {Journal of Applied Physics}, |
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Keywords = {nanoparticles; suspensions; stochastic processes; Brownian motion; heat transfer; thermal conductivity; two-phase flow}, |
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Local-Url = {file://localhost/Users/charles/Documents/Papers/JApplPhys_100_043507.pdf}, |
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Number = {4}, |
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Numpages = {6}, |
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Pages = {043507}, |
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Publisher = {AIP}, |
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Title = {Stochastic thermal transport of nanoparticle suspensions}, |
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Url = {http://link.aip.org/link/?JAP/100/043507/1}, |
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Volume = {100}, |
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Year = {2006}} |
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@article{Henglein:1999fk, |
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Abstract = {Colloidal silver sols of long-time stability are formed in the gamma-irradiation of 1.0 x 10(-4) M AgClO4 solutions, which also contain 0.3 M 2-propanol, 2.5 x 10(-2) M N2O, and sodium citrate in various concentrations. The reduction of Ag+ in these solutions is brought about by the I-hydroxyalkyl radical generated in the radiolysis of 2-propanol; citrate does not act as a reductant but solely as a stabilizer of the colloidal particles formed. Its concentration is varied in the range from 5.0 x 10(-5) to 1.5 x 10(-3) M, and the size and size distribution of the silver particles are studied by electron microscopy. At low citrate concentration, partly agglomerated large particles are formed that have many imperfections. In an intermediate range (a few 10(-4) M), well-separated particles with a rather narrow size distribution and little imperfections are formed, the size slightly decreasing with increasing citrate concentration. At high citrate concentrations, large lumps of coalesced silver particles are present, due to destabilization by the high ionic strength of the solution. These findings are explained by two growth mechanisms: condensation of small silver clusters (type-I growth), and reduction of Ag+ on silver particles via radical-to-particle electron transfer (type-II growth). The particles formed in the intermediate range of citrate concentration were studied by high-resolution electron microscopy and computer simulations. They constitute icosahedra and cuboctahedra.}, |
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Author = {Henglein, A and Giersig, M}, |
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Date-Added = {2007-09-07 18:11:39 -0400}, |
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Date-Modified = {2007-09-07 18:17:03 -0400}, |
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Journal = {Journal of Physical Chemistry B}, |
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Local-Url = {file://localhost/Users/charles/Documents/Papers/jp9925334.pdf}, |
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Pages = {9533-9539}, |
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Title = {Formation of colloidal silver nanoparticles: Capping action of citrate}, |
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Volume = {103}, |
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Year = {1999}} |
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@article{Link:2000lr, |
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Abstract = {Driven by the search for new materials with interesting and unique properties and also by the fundamental question of how atomic and molecular physical behaviour develops with increasing size, the field of nanoparticle research has grown immensely in the last two decades. Partially for these reasons, colloidal solutions of metallic (especially silver and gold) nanoparticles have long fascinated scientists because of their very intense colours. The intense red colour of colloidal gold nanoparticles is due to their surface plasmon absorption. This article describes the physical origin of the surface plasmon absorption in gold nanoparticles with emphasis on the Mie and also the Maxwell-Garnett theory and reviews the effects of particle size and shape on the resonance condition. A better understanding of the relationship between the optical absorption spectrum (in particular, the plasmon resonance) and such particle properties as its dimensions or surrounding environment can prove fruitful for the use of the plasmon absorption as an analytical tool. The plasmon resonance has also had a great impact on the Raman spectrum of surface-adsorbed molecules and a large enhancement of the fluorescence quantum yield of gold nanorods is observed. Furthermore, following the changes in the plasmon absorption induced by excitation (heating) with ultrashort laser pulses allows one to monitor the electron dynamics (electron-electron and electron-phonon interactions) in real time, which is important in understanding such fundamental questions regarding the thermal and electrical conductivity of these nanoparticles. Very intense heating with laser pulses leads to structural changes of the nanoparticles (nuclear rearrangements in the form of melting and fragmentation). ABSTRACT FROM AUTHOR Copyright of International Reviews in Physical Chemistry is the property of Taylor \& Francis Ltd and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts)}, |
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Abstract1 = {Driven by the search for new materials with interesting and unique properties and also by the fundamental question of how atomic and molecular physical behaviour develops with increasing size, the field of nanoparticle research has grown immensely in the last two decades. Partially for these reasons, colloidal solutions of metallic (especially silver and gold) nanoparticles have long fascinated scientists because of their very intense colours. The intense red colour of colloidal gold nanoparticles is due to their surface plasmon absorption. This article describes the physical origin of the surface plasmon absorption in gold nanoparticles with emphasis on the Mie and also the Maxwell-Garnett theory and reviews the effects of particle size and shape on the resonance condition. A better understanding of the relationship between the optical absorption spectrum (in particular, the plasmon resonance) and such particle properties as its dimensions or surrounding environment can prove fruitful for the use of the plasmon absorption as an analytical tool. The plasmon resonance has also had a great impact on the Raman spectrum of surface-adsorbed molecules and a large enhancement of the fluorescence quantum yield of gold nanorods is observed. Furthermore, following the changes in the plasmon absorption induced by excitation (heating) with ultrashort laser pulses allows one to monitor the electron dynamics (electron-electron and electron-phonon interactions) in real time, which is important in understanding such fundamental questions regarding the thermal and electrical conductivity of these nanoparticles. Very intense heating with laser pulses leads to structural changes of the nanoparticles (nuclear rearrangements in the form of melting and fragmentation). ABSTRACT FROM AUTHOR Copyright of International Reviews in Physical Chemistry is the property of Taylor \& Francis Ltd and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts)}, |
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Annote = {Accession Number: 3844873; Link, Stephan 1 El-Sayed, Mostafa A. 1; Affiliations: 1: Laser Dynamics Laboratory, School of Chemistry and Biochemistry, Georgia Institute of Technology, Atlanta, GA 30332-0400, USA; Source Information: Jul/Sep2000, Vol. 19 Issue 3, p409; Subject Term: MOLECULAR structure; Subject Term: NANOPARTICLES; Number of Pages: 45p; Document Type: Article}, |
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Author = {Link, Stephan and El-Sayed, Mostafa A.}, |
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Date-Added = {2007-09-07 16:21:48 -0400}, |
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Date-Modified = {2007-09-07 16:21:55 -0400}, |
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Isbn = {0144235X}, |
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J1 = {International Reviews in Physical Chemistry}, |
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Journal = {International Reviews in Physical Chemistry}, |
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Journal1 = {International Reviews in Physical Chemistry}, |
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Keywords = {MOLECULAR structure; NANOPARTICLES}, |
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Local-Url = {file://localhost/Users/charles/Documents/Papers/3844873.pdf}, |
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M3 = {Article}, |
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Number = {3}, |
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Pages = {409--453}, |
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Publisher = {Taylor \& Francis Ltd}, |
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Title = {Shape and size dependence of radiative, non-radiative and photothermal properties of gold nanocrystals.}, |
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Ty = {JOUR}, |
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Url = {http://search.ebscohost.com/login.aspx?direct=true&AuthType=ip,url,uid,cookie&db=afh&AN=3844873&site=ehost-live}, |
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Volume = {19}, |
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Year = {2000}} |
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@article{BROOKS:1985kx, |
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Author = {BROOKS, CL and BRUNGER, A and KARPLUS, M}, |
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Date-Added = {2007-09-06 15:55:51 -0400}, |
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Year = {1983}} |
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@book{Strandburg:1992qy, |
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Address = {New York }, |
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Address = {New York}, |
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Annote = {LDR 01152pam 2200301 a 4500 |
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001 2960109 |
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005 19920314112708.5 |
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Isbn = {0387976388 (U.S. : alk. paper)}, |
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Library-Id = {91020237}, |
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Publisher = {Springer-Verlag}, |
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Title = {Bond-orientational order in condensed matter systems }, |
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Title = {Bond-orientational order in condensed matter systems}, |
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Year = {1992}} |
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@book{Kittel:1996fk, |
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Address = {New York }, |
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Address = {New York}, |
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Annote = {LDR 01170cam 2200289 a 4500 |
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001 1143187 |
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005 20060719213349.0 |
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Isbn = {0471111813 (alk. paper)}, |
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Library-Id = {95018445}, |
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Publisher = {Wiley}, |
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Title = {Introduction to solid state physics }, |
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Title = {Introduction to solid state physics}, |
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Url = {http://www.loc.gov/catdir/description/wiley033/95018445.html}, |
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Year = {1996}} |
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