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This book covers the main physical mechanisms and the different contributions (1/f noise, shot noise, etc.) behind electronic fluctuations in various spintronic devices. It presents the first comprehensive summary of fundamental noise mechanisms in both electronic and spintronic devices and is therefore unique in that aspect.
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This book covers the main physical mechanisms and the different contributions (1/f noise, shot noise, etc.) behind electronic fluctuations in various spintronic devices. It presents the first comprehensive summary of fundamental noise mechanisms in both electronic and spintronic devices and is therefore unique in that aspect.
Produktdetails
- Produktdetails
- Verlag: Jenny Stanford Publishing
- Seitenzahl: 352
- Erscheinungstermin: 23. August 2018
- Englisch
- Abmessung: 229mm x 152mm x 21mm
- Gewicht: 640g
- ISBN-13: 9789814774345
- ISBN-10: 9814774340
- Artikelnr.: 54401601
- Verlag: Jenny Stanford Publishing
- Seitenzahl: 352
- Erscheinungstermin: 23. August 2018
- Englisch
- Abmessung: 229mm x 152mm x 21mm
- Gewicht: 640g
- ISBN-13: 9789814774345
- ISBN-10: 9814774340
- Artikelnr.: 54401601
Farkhad G. Aliev is a professor of condensed matter physics at the Faculty of Science, Universidad Autonoma de Madrid (UAM), Spain. He teaches undergraduate and graduate courses on mathematics and physics. Prior to this, he conducted research as scientist at M.V. Lomonosov Moscow State University, Moscow, Russia (1984-1995), and as visiting professor at UAM (1990-1995) working in the field of heavy fermion and high-Tc superconductivity and thermoelectric properties of half-Heusler compounds. His focus shifted to spintronics and nanomagnetism since 1995 during his stay as research professor at Katholeike Universiteit Leuven, Belgium. Currently he leads the MAGNETRANS group created at UAM in 2001 which focuses on experimental studies of noise and magnetization dynamics in magnetic nanostructures. His research interests also include vortex dynamics in superconductors and lateral photovoltaic effect in ferromagnet/semiconductor patterned structures. He is co-author of more than 150 publications referenced in ISI-WEB and 4 patents and co-editor of a textbook. He has directed 9 PhD theses, has been publication editor of Magnetism and Magnetic Materials (MMM2016) conference proceedings and is on the editorial board of Scientific Reports. Juan Pedro Cascales is a postdoctoral researcher at the Francis Bitter Magnet Laboratory at the Massachusetts Institute of Technology (MIT). He obtained his PhD in condensed matter physics and nanotechnology from the Universidad Autónoma de Madrid, Spain, in 2015 under the supervision of Prof. Farkhad Aliev. His research centers around the investigation of the fundamental aspects of electron transport in various types of spintronic devices, combining magnetic, topological insulator, organic and/or superconducting materials by thin-film evaporation and the study of conductance and voltage fluctuations (or noise) at cryogenic temperatures. He has co-authored 15 publications that are referenced in ISI-WEB and 1 patent.
Introduction. Noise in spintronic systems. Experimental methods. Noise in
metallic spin valves. Shot noise in single barrier magnetic tunnel
junctions. Frequency dependent noise in single barrier magnetic tunnel
junctions. Interplay between spin-torque and noise in sub-100nm size
magnetic tunnel junctions. Magnetoresistance and noise in magnetic tunnel
junctions with optimized interface mismatch. Noise in double barrier
magnetic tunnel junctions. Low frequency noise in organic electronics and
spintronics. Electron transport and noise in small dots connected to
ferromagnetic leads. Charge and spin transport and noise in two dimensional
materials. Magnetoresistive sensors: operation principles and noise.
Outlook and perspectives.
metallic spin valves. Shot noise in single barrier magnetic tunnel
junctions. Frequency dependent noise in single barrier magnetic tunnel
junctions. Interplay between spin-torque and noise in sub-100nm size
magnetic tunnel junctions. Magnetoresistance and noise in magnetic tunnel
junctions with optimized interface mismatch. Noise in double barrier
magnetic tunnel junctions. Low frequency noise in organic electronics and
spintronics. Electron transport and noise in small dots connected to
ferromagnetic leads. Charge and spin transport and noise in two dimensional
materials. Magnetoresistive sensors: operation principles and noise.
Outlook and perspectives.
Introduction. Noise in spintronic systems. Experimental methods. Noise in
metallic spin valves. Shot noise in single barrier magnetic tunnel
junctions. Frequency dependent noise in single barrier magnetic tunnel
junctions. Interplay between spin-torque and noise in sub-100nm size
magnetic tunnel junctions. Magnetoresistance and noise in magnetic tunnel
junctions with optimized interface mismatch. Noise in double barrier
magnetic tunnel junctions. Low frequency noise in organic electronics and
spintronics. Electron transport and noise in small dots connected to
ferromagnetic leads. Charge and spin transport and noise in two dimensional
materials. Magnetoresistive sensors: operation principles and noise.
Outlook and perspectives.
metallic spin valves. Shot noise in single barrier magnetic tunnel
junctions. Frequency dependent noise in single barrier magnetic tunnel
junctions. Interplay between spin-torque and noise in sub-100nm size
magnetic tunnel junctions. Magnetoresistance and noise in magnetic tunnel
junctions with optimized interface mismatch. Noise in double barrier
magnetic tunnel junctions. Low frequency noise in organic electronics and
spintronics. Electron transport and noise in small dots connected to
ferromagnetic leads. Charge and spin transport and noise in two dimensional
materials. Magnetoresistive sensors: operation principles and noise.
Outlook and perspectives.