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Livres sur le sujet « Nanoscale Dimensions »

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Auteur : Grafiati
Publié le 7 septembre 2023

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1

Meeting, Materials Research Society, et Symposium II, "Probing Mechanics at Nanoscale Dimensions" (2009 : San Francisco, Calif.), dir. Probing mechanics at nanoscale dimensions : Symposium held April 14-17, 2009, San Francisco, California, U.S.A. Warrendale, PA : Materials Research Society, 2009.

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2

Ünlü, Hilmi, et Norman J. M. Horing, dir. Progress in Nanoscale and Low-Dimensional Materials and Devices. Cham : Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-030-93460-6.

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3

Li, Zhenyu. One-Dimensional nanostructures : Electrospinning Technique and Unique Nanofibers. Berlin, Heidelberg : Springer Berlin Heidelberg, 2013.

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4

Ünlü, Hilmi. Low Dimensional Semiconductor Structures : Characterization, Modeling and Applications. Berlin, Heidelberg : Springer Berlin Heidelberg, 2013.

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5

Günter, Wilkening, et Koenders Ludger, dir. Nanoscale calibration standards and methods : Dimensional and related measurements in the micro- and nanometer range. Weinheim : Wiley-VCH, 2005.

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6

Filatov, D. O. Two-dimensional periodic nanoscale patterning of solid surfaces by four-beam standing wave excimer laser lithography. New York : Nova Science Pub. Inc., 2010.

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7

Isotope low-dimensional structures : Elementary excitations and applications. Heidelberg : Springer, 2012.

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8

Bhattacharya, Sitangshu. Effective Electron Mass in Low-Dimensional Semiconductors. Berlin, Heidelberg : Springer Berlin Heidelberg, 2013.

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9

Friedman, Lawrence, Nobumichi Taumura, Andrew Minor et Conal Murray. Probing Mechanics at Nanoscale Dimensions : Volume 1185. University of Cambridge ESOL Examinations, 2014.

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10

Tiwari, Sandip. Nanoscale transistors. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198759874.003.0002.

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This chapter brings together the physical underpinnings of field-effect transistors operating in their nanoscale limits. It tackles the change in dominant behavior from scattering-limited long-channel transport to mesoscopic and few scattering events limits in quantized channels. It looks at electrostatics and a transistor’s controllability as dimensions are shrunk—the interplay of geometry and control—and then brings out the operational characteristics in “off”-state, e.g., the detailed nature of insulator’s implications or threshold voltage’s statistical variations grounded in short-range and long-range effects, and “on”-state, where quantization, quantized channels, ballistic transport and limited scattering are important. It also explores the physical behavior for zero bandgap and monoatomic layer materials by focusing on real-space and reciprocal-space funneling as one of the important dimensional change consequences through a discussion of parasitic resistances.
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11

Lepri, Stefano. Thermal Transport in Low Dimensions : From Statistical Physics to Nanoscale Heat Transfer. Springer London, Limited, 2016.

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12

Lepri, Stefano. Thermal Transport in Low Dimensions : From Statistical Physics to Nanoscale Heat Transfer. Springer, 2016.

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13

author, Shinn Terry, dir. Toward a new dimension : Exploring the nanoscale. Oxford University Press, 2014.

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14

Low-Dimensional Nanoscale Systems on Discrete Spaces. World Scientific Publishing Company, 2007.

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15

Fu, Huaxiang. Unusual properties of nanoscale ferroelectrics. Sous la direction de A. V. Narlikar et Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.19.

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This article describes the unusual properties of nanoscale ferroelectrics (FE), including widely tunable polarization and improved properties in strained ferroelectric thin films; polarization enhancement in superlattices; polarization saturation in ferroelectric thin films under very large inplane strains; occurrence of ferroelectric phase transitions in one-dimensional wires; existence of the toroidal structural phase in ferroelectric nanoparticles; and the symmetry-broken phase-transition path when one transforms a vortex phase into a polarization phase. The article first considers some of the critical questions on low-dimensional ferroelectricity before discussing the theoretical approaches used to determine the properties of ferroelectric nanostructures. It also looks at 2D ferroelectric structures such as surfaces, superlattices and thin films, along with 1D ferroelectric nanowires and ferroelectric nanoparticles.
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16

Douglas, Shawn Michael. Self-assembly of DNA into nanoscale three-dimensional shapes. 2009.

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17

Li, Zhenyu, et Ce Wang. One-Dimensional nanostructures : Electrospinning Technique and Unique Nanofibers. Springer, 2013.

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18

Kanda, A., Y. Ootuka, K. Kadowaki et F. M. Peeters. Novel superconducting states in nanoscale superconductors. Sous la direction de A. V. Narlikar et Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533046.013.19.

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This article describes novel superconducting states in nanoscale superconductors. It first considers characteristic lengths in superconductors and vortices in mesoscopic superconductors before discussing trends in superconductivity research, which is closely related to recent progress in nanotechnology. It then explains the theoretical methods used for the study of mesoscopic superconducting states, along with theoretical predictions of vortex states in thin mesoscopic superconducting films. It also looks at experimental techniques used for the detection of vortices, including direct visualization of the vortex positions and indirect methods such as the multiple-small-tunnel-junction method, and experimental detection of mesoscopic vortex states in disks and squares. Finally, it evaluates one-dimensional vortex in mesoscopic rings.
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19

Horing, Norman J. M., et Hilmi Ünlü. Low Dimensional Semiconductor Structures : Characterization, Modeling and Applications. Springer Berlin / Heidelberg, 2014.

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20

Horing, Norman J. M., et Hilmi Ünlü. Low Dimensional Semiconductor Structures : Characterization, Modeling and Applications. Springer, 2012.

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21

Wilkening, Günter, et Ludger Koenders. Nanoscale Calibration Standards and Methods : Dimensional and Related Measurements in the Micro and Nanometer Range. Wiley & Sons, Incorporated, John, 2006.

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22

Horing, Norman J. M., et Hilmi Ünlü. Progress in Nanoscale and Low-Dimensional Materials and Devices : Properties, Synthesis, Characterization, Modelling and Applications. Springer International Publishing AG, 2022.

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23

Wilkening, Günter, et Ludger Koenders. Nanoscale Calibration Standards and Methods : Dimensional and Related Measurements in the Micro- and Nanometer Range. Wiley-VCH, 2005.

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24

Wilkening, Günter, et Ludger Koenders. Nanoscale Calibration Standards and Methods : Dimensional and Related Measurements in the Micro and Nanometer Range. Wiley-VCH Verlag GmbH, 2006.

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25

Gang, Chen, Mildred S. Dresselhaus, Gene Dresselhaus et Joseph P. Heremans. Thermoelectricity : Thermoelectric And Thermomagnetic Properties in Low-dimensional And Nanoscale Materials (Engineering Materials and Processes). Springer-Verlag, 2008.

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26

Narlikar, A. V., et Y. Y. Fu, dir. Oxford Handbook of Nanoscience and Technology. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.001.0001.

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This Handbook presents important developments in the field of nanoscience and technology, focusing on the advances made with a host of nanomaterials including DNA and protein-based nanostructures. Topics include: optical properties of carbon nanotubes and nanographene; defects and disorder in carbon nanotubes; roles of shape and space in electronic properties of carbon nanomaterials; size-dependent phase transitions and phase reversal at the nanoscale; scanning transmission electron microscopy of nanostructures; the use of microspectroscopy to discriminate nanomolecular cellular alterations in biomedical research; holographic laser processing for three-dimensional photonic lattices; and nanoanalysis of materials using near-field Raman spectroscopy. The volume also explores new phenomena in the nanospace of single-wall carbon nanotubes; ZnO wide-bandgap semiconductor nanostructures; selective self-assembly of semi-metal straight and branched nanorods on inert substrates; nanostructured crystals and nanocrystalline zeolites; unusual properties of nanoscale ferroelectrics; structural, electronic, magnetic, and transport properties of carbon-fullerene-based polymers; fabrication and characterization of magnetic nanowires; and properties and potential of protein-DNA conjugates for analytic applications.
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27

Ghatak, Kamakhya Prasad, et Sitangshu Bhattacharya. Effective Electron Mass in Low-Dimensional Semiconductors. Springer, 2014.

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28

Benisty, Henri, Jean-Jacques Greffet et Philippe Lalanne. Introduction to Nanophotonics. Oxford University Press, 2022. http://dx.doi.org/10.1093/oso/9780198786139.001.0001.

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The aim of this book is to cover the scope of Nanophotonics, a discipline that has emerged around the turn of the millennium. It results from the merge of different communities working in different aspects of light-matter interaction at the nanoscale. These include near-field optics and super-resolution microscopy, photonic crystals, diffractive optics, plasmonics, optoelectronics, synthesis of metallic and semiconductor nanoparticles, two-dimensional materials and metamaterials. Our feeling when we started the project was that a book covering most of these aspects altogether was lacking. The field is so rapidly evolving that it is impossible to summarize all the recent breakthroughs. The goal of this book is to provide a self-contained discussion of the fundamentals of the different subfields involved in nanophotonics. The current project is a collaborative project between three researchers that have been actively involved in the field from different communities. Henri Benisty has a background in semiconductor physics and optoelectronics, Jean-Jacques Greffet has a background in near-field optics and light scattering, Philippe Lalanne has a background in diffractive optics and photonic crystals. All of them made significant contributions to the advancement of the field. The book material is based on lectures that have been given by them at the Institut d’Optique Graduate School (Palaiseau, Bordeaux and Saint-Etienne).
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