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Frontiers in Electronic Materials


Frontiers in Electronic Materials

Correlation Effects, Spintronics, and Memristive Phenomena - Fundamentals and Application
1. Aufl.

von: Jörg Heber, Darrell Schlom, Yoshinori Tokura, Rainer Waser, Matthias Wuttig

178,99 €

Verlag: Wiley-VCH
Format: EPUB
Veröffentl.: 02.04.2013
ISBN/EAN: 9783527667727
Sprache: englisch
Anzahl Seiten: 692

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Beschreibungen

This collection of extended abstracts summarizes the latest research as presented at "Frontiers in Electronic Materials", a Nature conference on correlation effects and memristive phenomena, which took place in 2012. <p>The contributions from leading authors from the US, Japan, Korea, and Europe discuss breakthroughs and challenges in fundamental research as well as the potential for future applications.</p> <p>Hot topics covered include:</p> <ul> <li>Electron correlation and unusual quantum effects</li> <li>Oxide heterostructures and interfaces</li> <li>Multiferrroics, spintronics, ferroelectrics and flexoelectrics</li> <li>Processing in nanotechnology</li> <li>Advanced characterization techniques</li> <li>Superionic conductors, thermoelectrics, photovoltaics</li> <li>Chip architectures and computational concepts</li> </ul> <p>An essential resource for the researchers of today and tomorrow.</p>
<p><b>Invited Talks 29</b></p> <p>Nanosessions 69</p> <p>Nanosession: 2D electron systems - Atomic configurations 71</p> <p>Nanosession: 2D electron systems - Correlation effects and transport 81</p> <p>Nanosession: 2D electron systems - Electronic structure and field effects 89</p> <p>Nanosession: Calorics 99</p> <p>Nanosession: Topological effects 109</p> <p>Nanosession: Mott insulators and transitions 115</p> <p>Nanosession: Advanced spectroscopy and scattering 123</p> <p>Nanosession: High-resolution transmission electron microscopy 133</p> <p>Nanosession: New technologies for scanning probes 143</p> <p>Nanosession: Phase change materials 155</p> <p>Nanosession: Phase change memories 163</p> <p>Nanosession: Scanning probe microscopy on oxides 177</p> <p>Nanosession: Logic devices and circuit design 185</p> <p>Nanosession: Neuromorphic concepts 197</p> <p>Nanosession: Electrochemical metallization memories 207</p> <p>Nanosession: Valence Change Memories - redox mechanism and modelling 219</p> <p>Nanosession: Valence Change Memories - a look inside 233</p> <p>Nanosession: Variants of resistive switching 247</p> <p>Nanosession: Magnetic interfaces and surfaces 259</p> <p>Nanosession: Ionics - lattice disorder and grain boundaries 269</p> <p>Nanosession: Ionics - redox kinetics, ion transport, and interfaces 281</p> <p>Nanosession: Spin dynamics 291</p> <p>Nanosession: Spin injection and transport 301</p> <p>Nanosession: Spin tunneling systems 311</p> <p>Nanosession: Multiferroic thin films and heterostructures 323</p> <p>Nanosession: Multiferroics - ordering phenomena 335</p> <p>Nanosession: Multiferroics - high transition temperatures 347</p> <p>Nanosession: Superconductivity 367</p> <p>Nanosession: Interplay between strain and electronic structure in metal oxides 377</p> <p>Nanosession: Photovoltaics, photocatalysis, and optical effects 389</p> <p>Nanosession: Ferroelectric interfaces 399</p> <p>Nanosession: Ferroelectrics - new and unusal material systems 409</p> <p>Nanosession: Atomic layer deposition 419</p> <p>Nanosession: Nanotechnological fabrication strategies 429</p> <p>Nanosession: Low-dimensional transport and ballistic effects 441</p> <p>Nanosession: Molecular and polymer electronics 453</p> <p>Nanosession: Carbon-based molecular systems 461</p> <p><b>Poster Sessions 471</b></p> <p>Poster: Electronic structure, lattice dynamics, and transport 473</p> <p>Poster: Memristive systems 523</p> <p>Poster: Spin-related phenomena 589</p> <p>Poster: Polar dielectrics, optics, and ionics 633</p> <p>Poster: Advances in technology and characterization 665</p>
<p>“Material researchers working in these areas would be able to use this book to quickly review the current state of the art in the respective areas of interest.”  (<i>IEEE Electrical Insulation Magazine</i>, 1 July 2013)</p>
Joerg Heber is senior editor of Nature Materials. He graduated in physics from the University of Erlangen (Germany), followed by a PhD in solid-state physics from Imperial College in 2000 and post-doc postions at Bell Labs (Murray Hill, NJ) and the University of Marburg (Germany), where he worked on semiconductor materials and optoelectronics. Having joined Nature Materials in March 2005, he handles manuscripts in fields such as condensed matter physics, photonics as well as metallurgy and related areas.<br> <br> Darrell Schlom is the Hebert Fisk Johnson Professor of Industrial Chemistry in the Department of Materials Science and Engineering at Cornell University. He is currently the chair of the Division of Materials Physics of the American Physical Society (APS). The focus of his research is the heteroepitaxial growth of oxide films by molecular-beam epitaxy. Darrell Schlom has published over 400 papers. He was elected Fellow of both APS and the Materials Research Society (MRS) and received an Alexander von Humboldt Research Fellowship and the MRS Medal. <br> <br> Yoshinori Tokura is Professor of Applied Physics at the University of Tokyo since 1994. Since 2007, he is also Group Director of RIKEN Advanced Science Institute. He has been investigating transition-metal oxide materials that exhibit strong electron correlation. With his research on giant magnetoelectric responses from multiferroics he extraordinarily contributed to the present knowledge on this topic. Professor Tokura was multiply awarded for his research achievements, among others with the Nishina Memorial Prize, Matthias Prize, Asahi Prize, MacGroddy Prize, and Fujihara Prize for correlated electron research.<br> <br> Rainer Waser is Professor at the faculty for Electrical Engineering and Information Technology at the RWTH Aachen University and director at the Peter Grunberg Institute at the Forschungszentrum Julich (FZJ), Germany. His research group is focused on fundamental aspects of electronic materials and on such integrated devices as nonvolatile memories, logic devices, sensors and actuators. Rainer Waser has published about 500 technical papers. Since 2003, he has been the coordinator of the research program on nanoelectronic systems within the Germany national research centres in the Helmholtz Association. In 2007, he has been co-founder of the Julich-Aachen Research Alliance, section Fundamentals of Future Information Technology (JARA-FIT).<br> <br> Matthias Wuttig is Professor for Physics of New Materials at the University of Aachen since 1997, and holds a JARA Professorship at Research Centre Julich & RWTH Aachen since 2011. He served as Dean of the Faculty of Mathematics, Informatics and Natural Sciences, and is Speaker of the strategy board of RWTH Aachen. He has been visiting professor in China, Kenya, USA, and Singapure. His research on phase change memories and organic thin films has been awarded several times, among others with the Heinz-Maier-Leibnitz Prize of the Ministry for Education and Science, the Gaede-Prize of the German Vacuum Society, and the Stanford R. Ovshinsky Prize. Since 2009, Matthias Wuttig is Einstein Professor at the Chinese Academy of Sciences.
Electronic materials are the basis of any device designed for modern applications in e.g. information technology or energy conversion. Investigating and perfecting the properties of materials for electronic uses is the research focus of many institutional and industrial research groups acting worldwide. A major challenge, however, is to both theoretically model and experimentally prepare these materials with sufficient quality, and to integrate them with adequate control so that these properties can be fully utilized.<br /> This publication summarizes cutting edge research presented at ?Frontiers in Electronic Materials?, a Nature Conference on Correlation Effects and Memristive Phenomena which took place in 2012. It comprises of contributions from leading authors in these fields who discuss breakthroughs and challenges in fundamental research as well as prospects for future applications.<br /> Topics covered:<br /> <ul> <li>Electron correlation and unusual quantum effects</li> <li>Oxide heterostructures and interfaces</li> <li>Multiferrroics, spintronics, ferroelectrics and flexoelectrics</li> <li>Processing in nanotechnology</li> <li>Advanced characterization techniques</li> <li>Superionic conductors, thermoelectrics, photovoltaics</li> <li>Chip architectures and computational concepts</li> </ul>

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