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Hiremath," Restoring the Connectivity in K-Connected MANET When All Edge Disjoint Minimum Spanning Trees Fail", IJCA Special Issue on "Mobile Ad-hoc Networks" MANETs, 2010, pp.148-152.
 Luan Lan and Hsu Wen-Jing," Localized Delaunay Triangulation for Topological Construction and Routing on MANETs
Title of Talk:
Investigations on the growth of quaternary nanomaterials Cu2In(1-X)GaxS2 and Cu2ZnSnS4 for solar cell devices.
Hua, Alessandro Vespignanib, Steven Pinkere, and César A.
Alexander Bagaturyants is chief researcher at Photochemistry Center of the Russian Academy of Sciences. He was graduated from D.I. Mendeleev Institute of Chemical Technology, Moscow, Russia in 1962, obtained his PhD degree, Dr. Sci. degree, and the academic title of professor in 1968, 1987, and 1992, respectively, all in physical chemistry. His main research interests are in the field of atomistic multiscale simulations of organic functional materials, quantum chemistry, quantum-chemical calculations of excited states in molecules and molecular complexes. Alexander Bagaturyants is the author of more than 200 research papers and two monographs.
Magnetic nanoparticles attract great interest due to their ever-increasing range of applications, including data storage, permanent magnets, catalysis, microwave absorption and optics, and more recently, a variety of uses in biomedicine, both for diagnosis (MRI contrast, magnetic particle imaging) and therapy (magnetic hyperthermia and drug delivery), i.e. in theranostics .In order to reach high efficiencies, most of the above applications necessarily rely on relative dense ensembles of magnetic nanoparticles, where (at least) dipolar interactions, and the corresponding demagnetizing field, become inevitably important. However, the effects of such interparticle (or intergrain) interactions are not yet fully understood, as they sometimes lead to complex collective behavior driven by magnetic frustration. In fact, there is a lack of robust analysis methods to even quantify the strength of interparticle interactions. A review of such methods is presented, highlighting our recent findings on arguably the most popular of them, namely the Henkel plots, which have been consistently shown by experiment and Monte Carlo simulations to be sensitive not only to interparticle interactions, as customarily assumed, but also to the subtle surface disorder frequently exhibited by oxide nanoparticles (ubiquitous in the mentioned applications).
Title of Talk: Nanocrystals as high temperature probes
At present time the most wide-spread at Northern Caucasus are Kabarday, Shapsygu, Bzhedygu and Chemgui idioms..." Examples of First Year Circassian Course Lessons include For more information see
The study of semiconductor nanocrystals (NCs) is a very active research field, due to the wide range of applications, related to light-emission and absorption, photodetection, solar cells, light emitting diode or tunable emitters for bio-labeling1. One area is the development of detection techniques with high spatial resolution enabled by the small size of nanomaterials. As a representative example, nanometer probes of temperature can be very useful to obtain an accurate local value of temperature, particularly in catalysis where the activity and selectivity are temperature dependent. The key is to obtain the value of the local temperature inside the solution or inside the solid at the surface of the reactants. Certain catalytic reactions require high temperatures to occur so another challenge is to build a high local temperature probe (> 373 K). In this context, semiconductor NCs are promising objects to provide this precision due to the temperature dependence of their optical properties. We present here the synthesis of different types of NCs (Cd3P22, InP@ZnS3 and CdSe@CdS4), their capacities as nanothermometers for high temperatures (>340 K) and the conditions which have to be fullfilled for accurate measurements. Different parameters such as the wavelength, the intensity, the area and the full width at half maximum of emission were studied as a function of temperature. The studied temperatures ranges from room temperature to 540 K and the comparison between the different NCs is discussed.
Title of Talk:Nanocrystals as high temperature probes
Title of Talk: Theory of Phonons in Multishell Microtubes
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Title of Talk:Theory of Phonons in Multishell Microtubes
Note: The shedule of speakers and their order of talks are subject to changes.
Centro Mixto Universidad de Sevilla-CSIC, Américo Vespucio 49, Spain
Title of Talk: Fabrication of Glancing Angle Deposited Metallic Nanorods on flat and Patterned Substrates
Centro Mixto Universidad de Sevilla-CSIC, Américo Vespucio 49, Spain
Dr. Hendricks is currently a Technical Group Supervisor, Project Manager, and ASME Fellow in the Power and Sensor Systems Section at NASA–Jet Propulsion Laboratory (JPL)/California Institute of Technology, Pasadena, CA, responsible for managing power system projects; and designing spacecraft power systems, solar power systems, nanotechnology in thermal management and thermal energy storage systems critical to NASA missions. Dr. Hendricks received his Ph.D. and Master of Science in Engineering from the University of Texas at Austin and Bachelor of Science in Physics from the University of Massachusetts at Lowell. He has over 35 years of professional experience in thermal & fluid systems, nanotechnology in energy recovery, conversion and storage systems, terrestrial and spacecraft power systems, and project management. Dr. Hendricks has authored or co-authored more than 85 publications, 2 invited book chapters, holds 9 patents, and is a registered Professional Engineer in California and Texas.
Venant, Thin Walled Structures, Torsional response Reference C.A.
Glancing angle deposited nanorods have attracted a great attention in many applications such as heat transfer, renewable energy, communication, electronic and electrical field, material science and engineering due to their unique properties. These nanorods are grown randomly with different morphologies and uncontrolled lengths and separation among the nanorods on flat substrates due to the shadowing effect occurs during the glancing angle deposition (GLAD) technique. Further enhancement of the performance of the GLAD nanorods is expected by controlling the morphology and separation among the nanorods by surface patterning. Hence, the goal of this work is to investigate the effect of surface pattering on the morphology and separation among the GLAD nanorods. To reach our goal, a combination of modified-nanosphere lithography (m-NSL) technique and GLAD technique is proposed to fabricate periodic and well-separated nanorods. For demonstration, Molybdenum (Mo), Chromium (Cr), and Copper (Cu) were used as source (target) materials due to their low cost and their availability in the laboratory. The results shows that the periodic Mo, Cr, and Cu nanorods has better separation among the nanorods than those grown on flat substrates, while they are larger in diameter and shorter in length. The periodic GLAD nanorods are also exhibited amazing structure that is flower-like or honeycomb-like structure since they are replicating the underlying patterned substrates.
What is Text to Speech – Amazon Web Services (AWS)
Title of Talk: Synthesis and characterization of gold nanoparticles supported on two different metal oxides prepared by impregnation with ionic exchange to form ferromagnetic nanostructures.
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