Active control of magnetoresistance of organic spin valves using ferroelectricity

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Abstract

Organic spintronic devices have been appealing because of the long spin lifetime of the charge carriers in the organic materials and their low cost, flexibility and chemical diversity. In previous studies, the control of resistance of organic spin valves is generally achieved by the alignment of the magnetization directions of the two ferromagnetic electrodes, generating magnetoresistance. Here we employ a new knob to tune the resistance of organic spin valves by adding a thin ferroelectric interfacial layer between the ferromagnetic electrode and the organic spacer: the magnetoresistance of the spin valve depends strongly on the history of the bias voltage, which is correlated with the polarization of the ferroelectric layer; the magnetoresistance even changes sign when the electric polarization of the ferroelectric layer is reversed. These findings enable active control of resistance using both electric and magnetic fields, opening up possibility for multi-state organic spin valves.

Abstract

Organic materials potentially offer a low-cost, flexible and environment-friendly route to spintronics. Here, the authors demonstrate an organic spin-valve device in which an electric field can control both the magnitude and the sign of magnetoresistance.

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Ferroelectric control of spin polarization.

V. Garcia, M. Bibes, L Bocher … (2010)

A current drawback of spintronics is the large power that is usually required for magnetic writing, in contrast with nanoelectronics, which relies on "zero-current," gate-controlled operations. Efforts have been made to control the spin-relaxation rate, the Curie temperature, or the magnetic anisotropy with a gate voltage, but these effects are usually small and volatile. We used ferroelectric tunnel junctions with ferromagnetic electrodes to demonstrate local, large, and nonvolatile control of carrier spin polarization by electrically switching ferroelectric polarization. Our results represent a giant type of interfacial magnetoelectric coupling and suggest a low-power approach for spin-based information control.

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Reversible electrical switching of spin polarization in multiferroic tunnel junctions.

D Pantel, S Goetze, Maike D. Hesse … (2012)

Spin-polarized transport in ferromagnetic tunnel junctions, characterized by tunnel magnetoresistance, has already been proven to have great potential for application in the field of spintronics and in magnetic random access memories. Until recently, in such a junction the insulating barrier played only a passive role, namely to facilitate electron tunnelling between the ferromagnetic electrodes. However, new possibilities emerged when ferroelectric materials were used for the insulating barrier, as these possess a permanent dielectric polarization switchable between two stable states. Adding to the two different magnetization alignments of the electrode, four non-volatile states are therefore possible in such multiferroic tunnel junctions. Here, we show that owing to the coupling between magnetization and ferroelectric polarization at the interface between the electrode and barrier of a multiferroic tunnel junction, the spin polarization of the tunnelling electrons can be reversibly and remanently inverted by switching the ferroelectric polarization of the barrier. Selecting the spin direction of the tunnelling electrons by short electric pulses in the nanosecond range rather than by an applied magnetic field enables new possibilities for spin control in spintronic devices.

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Efficiency enhancement in organic solar cells with ferroelectric polymers.

Yongbo Yuan, Timothy Reece, Pankaj Sharma … (2011)

The recombination of electrons and holes in semiconducting polymer-fullerene blends has been identified as a main cause of energy loss in organic photovoltaic devices. Generally, an external bias voltage is required to efficiently separate the electrons and holes and thus prevent their recombination. Here we show that a large, permanent, internal electric field can be ensured by incorporating a ferroelectric polymer layer into the device, which eliminates the need for an external bias. The electric field, of the order of 50 V μm(-1), potentially induced by the ferroelectric layer is tens of times larger than that achievable by the use of electrodes with different work functions. We show that ferroelectric polymer layers enhanced the efficiency of several types of organic photovoltaic device from 1-2% without layers to 4-5% with layers. These enhanced efficiencies are 10-20% higher than those achieved by other methods, such as morphology and electrode work-function optimization. The devices show the unique characteristics of ferroelectric photovoltaic devices with switchable diode polarity and tunable efficiency.

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Author and article information

Journal

Journal ID (nlm-ta): Nat Commun

Journal ID (iso-abbrev): Nat Commun

Title: Nature Communications

Publisher: Nature Pub. Group

ISSN (Electronic): 2041-1723

Publication date (Electronic): 10 July 2014

Volume: 5

Electronic Location Identifier: 4396

Affiliations

[1 ]State Key Laboratory of Surface Physics and Department of Physics and Collaborative Innovation Center of Advanced Microstructure, Fudan University , Shanghai 200433, China

[2 ]Materials Science and Technology Division, Oak Ridge National Laboratory , Oak Ridge, Tennessee 37831, USA

[3 ]Department of Physics and Astronomy, University of Tennessee , Knoxville, Tennessee 37996, USA

[4 ]Center for Nanophase Materials Sciences, Oak Ridge National Laboratory , Oak Ridge, Tennessee 37831, USA

[5 ]Computer Science and Mathematics Division, Oak Ridge National Laboratory , Oak Ridge, Tennessee 37831, USA

[6 ]These authors contributed equally to this work

[7 ]Present address: Department of Physics and Astronomy, University of Utah, Salt Lake City, Utah 84112, USA

Author notes

[a ] xiaoshan.xu@ 123456unl.edu or to shenj5494@ 123456fudan.edu.cn

Article

Publisher Item ID: ncomms5396

DOI: 10.1038/ncomms5396

PMC ID: 4104453

PubMed ID: 25008155

SO-VID: 793cc9ad-4b52-4f2b-86d6-fde9acf73981

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This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by-nc-nd/4.0/

Active control of magnetoresistance of organic spin valves using ferroelectricity

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Most cited references 14

Ferroelectric control of spin polarization.

Reversible electrical switching of spin polarization in multiferroic tunnel junctions.

Efficiency enhancement in organic solar cells with ferroelectric polymers.

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