Domain Walls (PDF)
From Fundamental Properties to Nanotechnology Concepts
(Sprache: Englisch)
Technological evolution and revolution are both driven by the discovery of new functionalities, new materials and the design of yet smaller, faster, and more energy-efficient components. Progress is being made at a breathtaking pace, stimulated by the...
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Technological evolution and revolution are both driven by the discovery of new functionalities, new materials and the design of yet smaller, faster, and more energy-efficient components. Progress is being made at a breathtaking pace, stimulated by the rapidly growing demand for more powerful and readily available information technology. High-speed internet and data-streaming, home automation, tablets and smartphones are now "necessities" for our everyday lives.
Consumer expectations for progressively more data storage and exchange appear to be insatiable.
Oxide electronics is a promising and relatively new field that has the potential to trigger major advances in information technology. Oxide interfaces are particularly intriguing. Here, low local symmetry combined with an increased susceptibility to external fields leads to unusual physical properties distinct from those of the homogeneous bulk.
In this context, ferroic domain walls have attracted recent attention as a completely new type of oxide interface. In addition to their functional properties, such walls are spatially mobile and can be created, moved, and erased on demand. This unique degree of flexibility enables domain walls to take an active role in future devices and hold a great potential as multifunctional 2D systems for nanoelectronics. With domain walls as reconfigurable electronic 2D components, a new generation of
adaptive nano-technology and flexible circuitry becomes possible, that can be altered and upgraded throughout the lifetime of the device. Thus, what started out as fundamental research, at the limit of accessibility, is finally maturing into a promising concept for next-generation
technology.
Consumer expectations for progressively more data storage and exchange appear to be insatiable.
Oxide electronics is a promising and relatively new field that has the potential to trigger major advances in information technology. Oxide interfaces are particularly intriguing. Here, low local symmetry combined with an increased susceptibility to external fields leads to unusual physical properties distinct from those of the homogeneous bulk.
In this context, ferroic domain walls have attracted recent attention as a completely new type of oxide interface. In addition to their functional properties, such walls are spatially mobile and can be created, moved, and erased on demand. This unique degree of flexibility enables domain walls to take an active role in future devices and hold a great potential as multifunctional 2D systems for nanoelectronics. With domain walls as reconfigurable electronic 2D components, a new generation of
adaptive nano-technology and flexible circuitry becomes possible, that can be altered and upgraded throughout the lifetime of the device. Thus, what started out as fundamental research, at the limit of accessibility, is finally maturing into a promising concept for next-generation
technology.
Autoren-Porträt von Dennis Meier, Jan Seidel, Marty Gregg, Ramamoorthy Ramesh
Professor Dennis MeierDepartment of Materials Science and Engineering, Norwegian University of Science and Technology (NTNU), Trondheim.
Professor Jan Seidel
School of Materials Science & Engineering, UNSW Sydney.
Professor Marty Gregg
Centre for Nanostructured Media (CNM), Condensed Matter Physics and Materials Science, Queen's University Belfast.
Professor Ramamoorthy Ramesh
Purnendu Chatterjee Chair in Energy Technologies, Department of Materials Science and Engineering and Department of Physics, University of California, Berkeley.
Bibliographische Angaben
- Autoren: Dennis Meier , Jan Seidel , Marty Gregg , Ramamoorthy Ramesh
- 2020, 288 Seiten, Englisch
- Verlag: Oxford University Press
- ISBN-10: 0192607413
- ISBN-13: 9780192607416
- Erscheinungsdatum: 07.08.2020
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