Organic and Inorganic NanostructuresArtech House, 2005 - 268 lappuses The fast-growing world of nanotechnology promises to revolutionize microelectronics and optoelectronics with the production and application of materials, devices and systems at nanoscale (1 to 100 billionth of a meter). This book provides professionals and researchers with a comprehensive and up-to-date understanding of organic and inorganic nanostructures - materials formed by chemical routes that engineers can use to build a wide range of electronic devices and sensors. Practitioners gain insight into the selection and optimization of nanostructures for specific applications and the development of novel nanoelectronic and sensing devices. Moreover, the book provides a thorough overview of the most important research in the field, presents experimental methods of studying nanostructures and nanostructured materials, and offers a look at the future direction of nanoelectronics. |
No grāmatas satura
1.–3. rezultāts no 34.
148. lappuse
... dependence of the tunneling exponential factor on bias voltage . ( From : [ 48 ] . © 2004 IEE . Reprinted with ... dependence of the exponential factor on voltage transforms to the V2 dependence at large bias , due to the transformation ...
... dependence of the tunneling exponential factor on bias voltage . ( From : [ 48 ] . © 2004 IEE . Reprinted with ... dependence of the exponential factor on voltage transforms to the V2 dependence at large bias , due to the transformation ...
148. lappuse
... dependence of the tunneling exponential factor on bias voltage . ( From : [ 48 ] . © 2004 IEE . Reprinted with ... dependence of the exponential factor on voltage transforms to the V12 dependence at large bias , due to the transformation ...
... dependence of the tunneling exponential factor on bias voltage . ( From : [ 48 ] . © 2004 IEE . Reprinted with ... dependence of the exponential factor on voltage transforms to the V12 dependence at large bias , due to the transformation ...
249. lappuse
... dependence of the sensor response in Figure 7.36 shows that Urease is strongly inhibited by DVDP . However , the concentration dependence is not well pronounced , while Imidacloprid is a weaker inhibitor , but the concentra- tion dependence ...
... dependence of the sensor response in Figure 7.36 shows that Urease is strongly inhibited by DVDP . However , the concentration dependence is not well pronounced , while Imidacloprid is a weaker inhibitor , but the concentra- tion dependence ...
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acid adsorbed adsorption amphiphilic anti-IgG Appl applications atomic barrier beam biosensors calixarene CdS clusters CdS nanoparticles charged Chem chemical colloid Composite concentration Conducting Polymers dependence devices diffraction Dye-Sensitized Solar Cells electrical electrochemical electrodeposition electrolyte electron tunneling ellipsometry energy enzyme evaporation exciton experimental film thickness formation of CdS II-VI impurities inorganic interface Langmuir Langmuir-Blodgett Films Layer-by-Layer layers LB films Lett luminescence measurements membrane metal method microelectronics microscopy molecular monolayer Multilayer Nabok nano nanoclusters nanometers nanoparticles nanostructured nanostructured materials organic films oxide parameters particles Phthalocyanine Phys Plasmon polarization polycation Polyelectrolyte polyion proteins Quantum Dots range reactions refractive index Reprinted with permission resonance sample scanning Self-Assembled semiconductor nanoparticles sensitive Sensors shown in Figure silicon Single-Electron sol-gel Solar Cells solid-state solution spectra Spectroscopy spin coating SPR curves structure substrate superlattices Surface Plasmon Resonance technique temperature thin films Thin Solid Films tion transducer transistors two-dimensional typical voltage