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Molecular spintronicsfrom organic se...

Galbiati, Marta.

Molecular spintronicsfrom organic semiconductors to self-assembled monolayers /

Record Type:	Electronic resources : Monograph/item
Title/Author:	Molecular spintronicsby Marta Galbiati.
Reminder of title:	from organic semiconductors to self-assembled monolayers /
Author:	Galbiati, Marta.
Published:	Cham :Springer International Publishing :2016.
Description:	xix, 183 p. :ill., digital ;24 cm.
Contained By:	Springer eBooks
Subject:	SpintronicsResearch.
Online resource:	http://dx.doi.org/10.1007/978-3-319-22611-8
ISBN:	9783319226118$q(electronic bk.)

Molecular spintronicsfrom organic semiconductors to self-assembled monolayers /
Galbiati, Marta.

Molecular spintronicsfrom organic semiconductors to self-assembled monolayers /[electronic resource] :by Marta Galbiati. - Cham :Springer International Publishing :2016. - xix, 183 p. :ill., digital ;24 cm. - Springer theses,2190-5053. - Springer theses..

Introduction to spintronics -- Why bring organic and molecular electronics to spintronics -- State of the art in organic and molecular spintronics -- Introduction to Self-Assembled Monolayers -- SAMs based device fabrication and characterization -- Magneto-transport results in SAM based MTJs -- State of the art in Alq3-based spintronic devices -- Magneto-transport results in Alq3 based OSVs.

This thesis targets molecular or organic spintronics and more particularly the spin polarization tailoring opportunities that arise from the ferromagnetic metal/molecule hybridization at interfaces: the new concept of spinterface. Molecular or organic spintronics is an emerging research field at the frontier between organic chemistry and spintronics. The manuscript is divided into three parts, the first of which introduces the basic concepts of spintronics and advantages that molecules can bring to this field. The state of the art on organic and molecular spintronics is also presented, with a special emphasis on the physics and experimental evidence for spinterfaces. The book's second and third parts are dedicated to the two main experimental topics investigated in the thesis: Self-Assembled Monolayers (SAMs) and Organic Semiconductors (OSCs) The study of SAMs-based magnetic tunnel nanojunctions reveals the potential to modulate the properties of such devices "at will," since each part of the molecule can be tuned independently like a "LEGO" building block. The study of Alq3-based spin valves reveals magnetoresistance effects at room temperature and is aimed at understanding the respective roles played by the two interfaces. Through the development of these systems, we demonstrate their potential for spintronics and provide a solid foundation for spin polarization engineering at the molecular level.

ISBN: 9783319226118$q(electronic bk.)

Standard No.: 10.1007/978-3-319-22611-8doiSubjects--Topical Terms:

737212
Spintronics
--Research.

LC Class. No.: TK7874.887

Dewey Class. No.: 621.381

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520 $a This thesis targets molecular or organic spintronics and more particularly the spin polarization tailoring opportunities that arise from the ferromagnetic metal/molecule hybridization at interfaces: the new concept of spinterface. Molecular or organic spintronics is an emerging research field at the frontier between organic chemistry and spintronics. The manuscript is divided into three parts, the first of which introduces the basic concepts of spintronics and advantages that molecules can bring to this field. The state of the art on organic and molecular spintronics is also presented, with a special emphasis on the physics and experimental evidence for spinterfaces. The book's second and third parts are dedicated to the two main experimental topics investigated in the thesis: Self-Assembled Monolayers (SAMs) and Organic Semiconductors (OSCs) The study of SAMs-based magnetic tunnel nanojunctions reveals the potential to modulate the properties of such devices "at will," since each part of the molecule can be tuned independently like a "LEGO" building block. The study of Alq3-based spin valves reveals magnetoresistance effects at room temperature and is aimed at understanding the respective roles played by the two interfaces. Through the development of these systems, we demonstrate their potential for spintronics and provide a solid foundation for spin polarization engineering at the molecular level.
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