Literature DB >> 26936817

Antiferromagnetic spintronics.

T Jungwirth1,2, X Marti1, P Wadley2, J Wunderlich1,3.   

Abstract

Antiferromagnetic materials are internally magnetic, but the direction of their ordered microscopic moments alternates between individual atomic sites. The resulting zero net magnetic moment makes magnetism in antiferromagnets externally invisible. This implies that information stored in antiferromagnetic moments would be invisible to common magnetic probes, insensitive to disturbing magnetic fields, and the antiferromagnetic element would not magnetically affect its neighbours, regardless of how densely the elements are arranged in the device. The intrinsic high frequencies of antiferromagnetic dynamics represent another property that makes antiferromagnets distinct from ferromagnets. Among the outstanding questions is how to manipulate and detect the magnetic state of an antiferromagnet efficiently. In this Review we focus on recent works that have addressed this question. The field of antiferromagnetic spintronics can also be viewed from the general perspectives of spin transport, magnetic textures and dynamics, and materials research. We briefly mention this broader context, together with an outlook of future research and applications of antiferromagnetic spintronics.

Year:  2016        PMID: 26936817     DOI: 10.1038/nnano.2016.18

Source DB:  PubMed          Journal:  Nat Nanotechnol        ISSN: 1748-3387            Impact factor:   39.213


  46 in total

1.  Creation of an antiferromagnetic exchange spring.

Authors:  A Scholl; M Liberati; E Arenholz; H Ohldag; J Stöhr
Journal:  Phys Rev Lett       Date:  2004-06-14       Impact factor: 9.161

2.  Experimental observation of the spin-Hall effect in a two-dimensional spin-orbit coupled semiconductor system.

Authors:  J Wunderlich; B Kaestner; J Sinova; T Jungwirth
Journal:  Phys Rev Lett       Date:  2005-02-04       Impact factor: 9.161

3.  Coulomb blockade anisotropic magnetoresistance effect in a (Ga,Mn)As single-electron transistor.

Authors:  J Wunderlich; T Jungwirth; B Kaestner; A C Irvine; A B Shick; N Stone; K-Y Wang; U Rana; A D Giddings; C T Foxon; R P Campion; D A Williams; B L Gallagher
Journal:  Phys Rev Lett       Date:  2006-08-15       Impact factor: 9.161

4.  Revealing the properties of Mn2Au for antiferromagnetic spintronics.

Authors:  V M T S Barthem; C V Colin; H Mayaffre; M-H Julien; D Givord
Journal:  Nat Commun       Date:  2013       Impact factor: 14.919

5.  Antiferromagnetic metal spintronics.

Authors:  A H MacDonald; M Tsoi
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2011-08-13       Impact factor: 4.226

6.  Domain-wall velocities of up to 750 m s(-1) driven by exchange-coupling torque in synthetic antiferromagnets.

Authors:  See-Hun Yang; Kwang-Su Ryu; Stuart Parkin
Journal:  Nat Nanotechnol       Date:  2015-02-23       Impact factor: 39.213

7.  Spin pumping and spin-transfer torques in antiferromagnets.

Authors:  Ran Cheng; Jiang Xiao; Qian Niu; Arne Brataas
Journal:  Phys Rev Lett       Date:  2014-07-29       Impact factor: 9.161

8.  Antiferromagnonic spin transport from Y3Fe5O12 into NiO.

Authors:  Hailong Wang; Chunhui Du; P Chris Hammel; Fengyuan Yang
Journal:  Phys Rev Lett       Date:  2014-08-29       Impact factor: 9.161

9.  Mn2Au: body-centered-tetragonal bimetallic antiferromagnets grown by molecular beam epitaxy.

Authors:  Han-Chun Wu; Zhi-Min Liao; R G Sumesh Sofin; Gen Feng; Xiu-Mei Ma; Alexander B Shick; Oleg N Mryasov; Igor V Shvets
Journal:  Adv Mater       Date:  2012-09-20       Impact factor: 30.849

10.  Phase-sensitive observation of a spin-orbital Mott state in Sr2IrO4.

Authors:  B J Kim; H Ohsumi; T Komesu; S Sakai; T Morita; H Takagi; T Arima
Journal:  Science       Date:  2009-03-06       Impact factor: 47.728
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  101 in total

1.  Electrical manipulation of a topological antiferromagnetic state.

Authors:  Hanshen Tsai; Tomoya Higo; Kouta Kondou; Takuya Nomoto; Akito Sakai; Ayuko Kobayashi; Takafumi Nakano; Kay Yakushiji; Ryotaro Arita; Shinji Miwa; Yoshichika Otani; Satoru Nakatsuji
Journal:  Nature       Date:  2020-04-20       Impact factor: 49.962

2.  Multi-stimuli manipulation of antiferromagnetic domains assessed by second-harmonic imaging.

Authors:  J-Y Chauleau; E Haltz; C Carrétéro; S Fusil; M Viret
Journal:  Nat Mater       Date:  2017-05-08       Impact factor: 43.841

3.  Electrically induced 2D half-metallic antiferromagnets and spin field effect transistors.

Authors:  Shi-Jing Gong; Cheng Gong; Yu-Yun Sun; Wen-Yi Tong; Chun-Gang Duan; Jun-Hao Chu; Xiang Zhang
Journal:  Proc Natl Acad Sci U S A       Date:  2018-08-03       Impact factor: 11.205

4.  Antiferromagnetic Domain Wall Motion Driven by Spin-Orbit Torques.

Authors:  Takayuki Shiino; Se-Hyeok Oh; Paul M Haney; Seo-Won Lee; Gyungchoon Go; Byong-Guk Park; Kyung-Jin Lee
Journal:  Phys Rev Lett       Date:  2016-08-16       Impact factor: 9.161

5.  Fast domain wall motion in the vicinity of the angular momentum compensation temperature of ferrimagnets.

Authors:  Kab-Jin Kim; Se Kwon Kim; Yuushou Hirata; Se-Hyeok Oh; Takayuki Tono; Duck-Ho Kim; Takaya Okuno; Woo Seung Ham; Sanghoon Kim; Gyoungchoon Go; Yaroslav Tserkovnyak; Arata Tsukamoto; Takahiro Moriyama; Kyung-Jin Lee; Teruo Ono
Journal:  Nat Mater       Date:  2017-09-25       Impact factor: 43.841

6.  Spontaneous exchange bias formation driven by a structural phase transition in the antiferromagnetic material.

Authors:  A Migliorini; B Kuerbanjiang; T Huminiuc; D Kepaptsoglou; M Muñoz; J L F Cuñado; J Camarero; C Aroca; G Vallejo-Fernández; V K Lazarov; J L Prieto
Journal:  Nat Mater       Date:  2017-11-20       Impact factor: 43.841

7.  Interface-Induced Phenomena in Magnetism.

Authors:  Frances Hellman; Axel Hoffmann; Yaroslav Tserkovnyak; Geoffrey S D Beach; Eric E Fullerton; Chris Leighton; Allan H MacDonald; Daniel C Ralph; Dario A Arena; Hermann A Dürr; Peter Fischer; Julie Grollier; Joseph P Heremans; Tomas Jungwirth; Alexey V Kimel; Bert Koopmans; Ilya N Krivorotov; Steven J May; Amanda K Petford-Long; James M Rondinelli; Nitin Samarth; Ivan K Schuller; Andrei N Slavin; Mark D Stiles; Oleg Tchernyshyov; André Thiaville; Barry L Zink
Journal:  Rev Mod Phys       Date:  2017-06-05       Impact factor: 54.494

8.  Real-space imaging of non-collinear antiferromagnetic order with a single-spin magnetometer.

Authors:  I Gross; W Akhtar; V Garcia; L J Martínez; S Chouaieb; K Garcia; C Carrétéro; A Barthélémy; P Appel; P Maletinsky; J-V Kim; J Y Chauleau; N Jaouen; M Viret; M Bibes; S Fusil; V Jacques
Journal:  Nature       Date:  2017-09-13       Impact factor: 49.962

9.  Layer Hall effect in a 2D topological axion antiferromagnet.

Authors:  Anyuan Gao; Yu-Fei Liu; Chaowei Hu; Jian-Xiang Qiu; Christian Tzschaschel; Barun Ghosh; Sheng-Chin Ho; Damien Bérubé; Rui Chen; Haipeng Sun; Zhaowei Zhang; Xin-Yue Zhang; Yu-Xuan Wang; Naizhou Wang; Zumeng Huang; Claudia Felser; Amit Agarwal; Thomas Ding; Hung-Ju Tien; Austin Akey; Jules Gardener; Bahadur Singh; Kenji Watanabe; Takashi Taniguchi; Kenneth S Burch; David C Bell; Brian B Zhou; Weibo Gao; Hai-Zhou Lu; Arun Bansil; Hsin Lin; Tay-Rong Chang; Liang Fu; Qiong Ma; Ni Ni; Su-Yang Xu
Journal:  Nature       Date:  2021-07-21       Impact factor: 49.962

10.  Reducing Dzyaloshinskii-Moriya interaction and field-free spin-orbit torque switching in synthetic antiferromagnets.

Authors:  Ruyi Chen; Qirui Cui; Liyang Liao; Yingmei Zhu; Ruiqi Zhang; Hua Bai; Yongjian Zhou; Guozhong Xing; Feng Pan; Hongxin Yang; Cheng Song
Journal:  Nat Commun       Date:  2021-05-25       Impact factor: 14.919
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