超快自旋动力学: 从飞秒磁学到阿秒磁学

杨旭; 冯红梅; 刘佳南; 张向群; 何为; 成昭华

doi:10.7498/aps.73.20240646

摘要

超快自旋动力学是研究材料受到外场激发后, 在皮秒至阿秒时间尺度下其自旋的运动行为. 随着激光技术的不断提升, 1996年开始的飞秒磁学成为磁学中的重要研究领域, 是实现更快响应的新型自旋电子学器件的重要技术途径. 尽管已有几十年的历史, 飞秒磁学依旧存在着非常多的物理问题尚未解决, 而理解这些问题需要研究更快时间尺度下的自旋动力学过程. 利用阿秒激光脉冲与磁性材料的相互作用, 可研究亚飞秒乃至阿秒时间尺度下、元素分辨的自旋动力学行为, 即阿秒磁学. 本文介绍了超快自旋动力学近年来的一些重要研究进展以及存在的问题, 阿秒磁学研究的机遇与挑战, 并对超快自旋动力学的未来发展趋势及前景进行分析与展望.

关键词:

Abstract

Ultrafast spin dynamics is the study of the evolution of spin degrees of freedom on a time scale from picoseconds to attoseconds after being excited by an external field. With the development of laser technology, ultrafast spin dynamics has presented new opportunities for realizing ultrafast spintronic devices since 1996. However, despite decades of development, many aspects of femtosecond magnetism remain unclear. Understanding the parameters of these ultrafast spin dynamics processes requires experiments on an even faster timescale. Attosecond magnetism and the interaction of attosecond laser pulses with magnetic materials can reveal spin dynamics on a sub-femtosecond to attosecond time scale. In this review, we first introduce the significant research progress, including the mechanisms of ultrafast demagnetization, all-optical switching, ultrafast spin currents, and terahertz waves. Secondly, we analyze the problems in ultrafast spin dynamics, such as the unclear physical mechanisms of ultrafast demagnetization, the uncertain relationship between magnetic damping and ultrafast demagnetization time, and the unexplored anisotropic ultrafast demagnetization. Thirdly, we discuss the opportunities and challenges in attosecond magnetism. Finally, we analyze and discuss the future development and prospects of ultrafast spin dynamics.

Keywords:

作者及机构信息

1.
松山湖材料实验室, 阿秒科学中心, 东莞　523808

2.
中国科学院物理研究所, 磁学国家重点实验室, 北京　100190

3.
中国科学院大学物理科学学院, 北京　100049

通信作者: 成昭华, zhcheng@iphy.ac.cn

Authors and contacts

1.
Attosecond Science Center, Songshan Lake Materials Laboratory, Dongguan 523808, China

2.
State Key Laboratory of Magnetism, Institute of Physics, Chinese Academy of Sciences, Beijing 100190, China

3.
School of Physical Sciences, University of Chinese Academy of Sciences, Beijing 100049, China

Corresponding author: Cheng Zhao-Hua, zhcheng@iphy.ac.cn

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参考文献

[1]	Kirilyuk A, Kimel A V, Rasing T 2010 Rev. Mod. Phys. 82 2731 Google Scholar
[2]	Walowski J, Münzenberg M 2016 J. Appl. Phys. 120 140901 Google Scholar
[3]	Farle M 1998 Rep. Prog. Phys. 61 755 Google Scholar
[4]	Kambersky V 1976 Czech. J. Phys. B 26 1366 Google Scholar
[5]	Beaurepaire E, Merle J C, Daunois A, Bigot J Y 1996 Phys. Rev. Lett. 76 4250 Google Scholar
[6]	Stanciu C D, Hansteen F, Kimel A V, Kirilyuk A, Tsukamoto A, Itoh A, Rasing T 2007 Phys. Rev. Lett. 99 047601 Google Scholar
[7]	Lambert C H, Mangin S, Varaprasad B S D C S, Takahashi Y K, Hehn M, Cinchetti M, Malinowski G, Hono K, Fainman Y, Aeschlimann M, Fullerton E E 2014 Science 345 1337 Google Scholar
[8]	Igarashi J, Zhang W, Remy Q, Diaz E, Lin J X, Hohlfeld J, Hehn M, Mangin S, Gorchon J, Malinowski G 2023 Nat. Mater. 22 725 Google Scholar
[9]	Huisman T J, Mikhaylovskiy R V, Costa J D, Freimuth F, Paz E, Ventura J, Freitas P P, Blugel S, Mokrousov Y, Rasing T, Kimel A V 2016 Nat. Nanotechnol. 11 455 Google Scholar
[10]	McPherson A, Gibson G, Jara H, Johann U, Luk T S, McIntyre I A, Boyer K, Rhodes C K 1987 J. Opt. Soc. Am. B 4 595 Google Scholar
[11]	Ferray M, L'Huillier A, Li X F, Lomprk L A, Mainfray G, Manus C 1988 J. Phys. B-At. Mol. Opt. 21 L31 Google Scholar
[12]	Nisoli M, Sansone G 2009 Prog. Quant. Electron. 33 17 Google Scholar
[13]	Siegrist F, Gessner J A, Ossiander M, Denker C, Chang Y P, Schroder M C, Guggenmos A, Cui Y, Walowski J, Martens U, Dewhurst J K, Kleineberg U, Munzenberg M, Sharma S, Schultze M 2019 Nature 571 240 Google Scholar
[14]	Li Y, Li Y, Liu Q, Xie Z K, Vetter E, Yuan Z, He W, Liu H L, Sun D L, Xia K, Yu W, Sun Y B, Zhao J J, Zhang X Q, Cheng Z H 2019 New J. Phys. 21 103040 Google Scholar
[15]	Tserkovnyak Y, Brataas A, Bauer G E 2002 Phys. Rev. Lett. 88 117601 Google Scholar
[16]	Katine J A, Albert F J, Buhrman R A 2000 Phys. Rev. Lett. 84 3149 Google Scholar
[17]	Ralph D C, Stiles M D 2008 J. Magn. Magn. Mater. 320 1190 Google Scholar
[18]	Soumyanarayanan A, Reyren N, Fert A, Panagopoulos C 2016 Nature 539 509 Google Scholar
[19]	Xiao D, Chang M C, Niu Q 2010 Rev. Mod. Phys. 82 1959 Google Scholar
[20]	Yang S A 2016 Spin 06 1640003 Google Scholar
[21]	Chen Y L, Analytis J G, Chu J H, Liu Z K, Mo S K, Qi X L, Zhang H J, Lu D H, Dai X, Fang Z, Zhang S C, Fisher I R, Hussain Z, Shen Z X 2009 Science 325 178 Google Scholar
[22]	Di Sante D, Barone P, Bertacco R, Picozzi S 2013 Adv. Mater. 25 509 Google Scholar
[23]	Manchon A, Koo H C, Nitta J, Frolov S M, Duine R A 2015 Nat. Mater. 14 871 Google Scholar
[24]	Sinova J, Valenzuela S O, Wunderlich J, Back C H, Jungwirth T 2015 Rev Mod Phys 87 1213 Google Scholar
[25]	Neubauer A, Pfleiderer C, Binz B, Rosch A, Ritz R, Niklowitz P G, Boni P 2009 Phys. Rev. Lett. 102 186602 Google Scholar
[26]	Yu X Z, Kanazawa N, Onose Y, Kimoto K, Zhang W Z, Ishiwata S, Matsui Y, Tokura Y 2011 Nat. Mater. 10 106 Google Scholar
[27]	Zhou C, Liu Y P, Wang Z, Ma S J, Jia M W, Wu R Q, Zhou L, Zhang W, Liu M K, Wu Y Z, Qi J 2018 Phys. Rev. Lett. 121 086801 Google Scholar
[28]	Zutic I, Fabian J, Das Sarma S 2004 Rev. Mod. Phys. 76 323 Google Scholar
[29]	Baibich M N, Broto J M, Fert A, Nguyen Van Dau F, Petroff F, Etienne P, Creuzet G, Friederich A, Chazelas J 1988 Phys. Rev. Lett. 61 2472 Google Scholar
[30]	Binasch G, Grunberg P, Saurenbach F, Zinn W 1989 Phys. Rev. B Condens. Matter. 39 4828 Google Scholar
[31]	Hashimoto S, Ochiai Y 1990 J. Magn. Magn. Mater. 88 211 Google Scholar
[32]	Cheng Z H, He W, Zhang X Q, Sun D L, Du H F, Wu Q, Ye J, Fang Y P, Liu H L 2015 Chin. Phys. B 24 077505 Google Scholar
[33]	Walowski J, Muller G, Djordjevic M, Munzenberg M, Klaui M, Vaz C A, Bland J A 2008 Phys. Rev. Lett. 101 237401 Google Scholar
[34]	Radu I, Woltersdorf G, Kiessling M, Melnikov A, Bovensiepen U, Thiele J U, Back C H 2009 Phys. Rev. Lett. 102 117201 Google Scholar
[35]	Guidoni L, Beaurepaire E, Bigot J Y 2002 Phys. Rev. Lett. 89 017401 Google Scholar
[36]	Graves C E, Reid A H, Wang T, et al. 2013 Nat. Mater. 12 293 Google Scholar
[37]	Bartelt A F, Comin A, Feng J, Nasiatka J R, Eimüller T, Ludescher B, Schütz G, Padmore H A, Young A T, Scholl A 2007 Appl. Phys. Lett. 90 162503 Google Scholar
[38]	Li Y, Zhang W, Li N, Sun R, Tang J, Gong Z Z, Li Y, Yang X, Xie Z K, Gul Q, Zhang X Q, He W, Cheng Z H 2019 J. Phys. Condens. Mat. 31 305802 Google Scholar
[39]	Zhang Q, Nurmikko A V, Miao G X, Xiao G, Gupta A 2006 Phys. Rev. B 74 064414 Google Scholar
[40]	Muller G M, Walowski J, Djordjevic M, Miao G X, Gupta A, Ramos A V, Gehrke K, Moshnyaga V, Samwer K, Schmalhorst J, Thomas A, Hutten A, Reiss G, Moodera J S, Munzenberg M 2009 Nat. Mater. 8 56 Google Scholar
[41]	Lu X Y, Lin Z Y, Pi H Q, Zhang T, Li G Q, Gong Y T, Yan Y, Ruan X Z, Li Y, Zhang H, Li L, He L, Wu J, Zhang R, Weng H M, Zeng C G, Xu Y B 2024 Nat. Commun. 15 2410 Google Scholar
[42]	Lichtenberg T, Schippers C F, van Kooten S C P, Evers S G F, Barcones B, Guimarães M H D, Koopmans B 2022 2D Mater. 10 015008 Google Scholar
[43]	Wu N, Zhang S J, Chen D Q, Wang Y X, Meng S 2024 Nat. Commun. 15 2804 Google Scholar
[44]	Khela M, Da Browski M, Khan S, Keatley P S, Verzhbitskiy I, Eda G, Hicken R J, Kurebayashi H, Santos E J G 2023 Nat. Commun. 14 1378 Google Scholar
[45]	Sun T, Zhou C, Jiang Z Z, Li X M, Qiu K, Xiao R C, Liu C X, Ma Z W, Luo X, Sun Y P, Sheng Z G 2021 2D Mater. 8 045040 Google Scholar
[46]	Da Browski M, Guo S, Strungaru M, Keatley P S, Withers F, Santos E J G, Hicken R J 2022 Nat. Commun. 13 5976 Google Scholar
[47]	Lee W J, Fernandez-Mulligan S, Tan H X, Yan C H, Guan Y D, Lee S H, Mei R B, Liu C X, Yan B H, Mao Z Q, Yang S L 2023 Nat. Phys. 19 950 Google Scholar
[48]	Padmanabhan H, Stoica V A, Kim P K, Poore M, Yang T N, Shen X Z, Reid A H, Lin M F, Park S, Yang J, Wang H Y, Koocher N Z, Puggioni D, Georgescu A B, Min L J, Lee S H, Mao Z Q, Rondinelli J M, Lindenberg A M, Chen L Q, Wang X J, Averitt R D, Freeland J W, Gopalan V 2022 Adv. Mater. 34 2202841 Google Scholar
[49]	Bartram F M, Leng Y C, Wang Y, Liu L, Chen X, Peng H, Li H, Yu P, Wu Y, Lin M L, Zhang J, Tan P H, Yang L 2022 npj Quantum. Mater. 7 84 Google Scholar
[50]	Evans R F L, Fan W J, Chureemart P, Ostler T A, Ellis M O A, Chantrell R W 2014 J. Phys. Condens. Matter. 26 103202 Google Scholar
[51]	Atxitia U, Chubykalo-Fesenko O 2011 Phys. Rev. B 84 144414 Google Scholar
[52]	Koopmans B, Ruigrok J J, Longa F D, de Jonge W J 2005 Phys. Rev. Lett. 95 267207 Google Scholar
[53]	Koopmans B, Malinowski G, Dalla Longa F, Steiauf D, Fahnle M, Roth T, Cinchetti M, Aeschlimann M 2010 Nat. Mater. 9 259 Google Scholar
[54]	Battiato M, Carva K, Oppeneer P M 2010 Phys. Rev. Lett. 105 027203 Google Scholar
[55]	Malinowski G, Dalla Longa F, Rietjens J H H, Paluskar P V, Huijink R, Swagten H J M, Koopmans B 2008 Nat. Phys. 4 855 Google Scholar
[56]	Schellekens A J, Kuiper K C, de Wit R R J C, Koopmans B 2014 Nat. Commun. 5 4333 Google Scholar
[57]	Li N, Sun Y B, Sun R, Yang X, Zhang W, Xie Z K, Liu J N, Li Y, Li Y, Gong Z Z, Zhang X Q, He W, Cheng Z H 2022 Phys. Rev. B 105 144415 Google Scholar
[58]	Hou Y S, Wu R Q 2019 Phys. Rev. Appl. 11 054032 Google Scholar
[59]	Gong Z H, Zhang W, Liu J N, Xie Z K, Yang X, Tang J, Du H F, Li N, Zhang X Q, He W, Cheng Z H 2023 Phys. Rev. B 107 144429 Google Scholar
[60]	Zhang X C, Shkurinov A, Zhang Y 2017 Nat. Photonics 11 16 Google Scholar
[61]	Pawar A Y, Sonawane D D, Erande K B, Derle D V 2013 Drug. Invent. Today 5 157 Google Scholar
[62]	Kampfrath T, Battiato M, Maldonado P, Eilers G, Notzold J, Mahrlein S, Zbarsky V, Freimuth F, Mokrousov Y, Blugel S, Wolf M, Radu I, Oppeneer P M, Munzenberg M 2013 Nat. Nanotechnol. 8 256 Google Scholar
[63]	Hirsch J E 1999 Phys. Rev. Lett. 83 1834 Google Scholar
[64]	Kato Y K, Myers R C, Gossard A C, Awschalom D D 2004 Science 306 1910 Google Scholar
[65]	Ando K, Takahashi S, Harii K, Sasage K, Ieda J, Maekawa S, Saitoh E 2008 Phys. Rev. Lett. 101 036601 Google Scholar
[66]	Rojas-Sanchez J C, Reyren N, Laczkowski P, Savero W, Attane J P, Deranlot C, Jamet M, George J M, Vila L, Jaffres H 2014 Phys. Rev. Lett. 112 106602 Google Scholar
[67]	Sun R, Yang S J, Yang X, Vetter E, Sun D L, Li N, Su L, Li Y, Li Y, Gong Z Z, Xie Z K, Hou K Y, Gul Q, He W, Zhang X Q, Cheng Z H 2019 Nano Lett. 19 4420 Google Scholar
[68]	Sun R, Yang S J, Yang X, Kumar A, Vetter E, Xue W H, Li Y, Li N, Li Y, Zhang S H, Ge B H, Zhang X Q, He W, Kemper A F, Sun D, Cheng Z H 2020 Adv. Mater. 32 2005315 Google Scholar
[69]	Qiu H S, Zhou L, Zhang C, Wu J, Tian Y, Cheng S, Mi S, Zhao H, Zhang Q, Wu D, Jin B, Chen J, Wu P 2020 Nat. Phys. 17 388 Google Scholar
[70]	Tang J, Ke Y J, He W, Zhang X Q, Zhang W, Li N, Zhang Y S, Li Y, Cheng Z H 2018 Adv. Mater. 30 1706439 Google Scholar
[71]	Kuiper K C, Roth T, Schellekens A J, Schmitt O, Koopmans B, Cinchetti M, Aeschlimann M 2014 Appl. Phys. Lett. 105 202402 Google Scholar
[72]	Zhang G P, Hubner W 2000 Phys. Rev. Lett. 85 3025 Google Scholar
[73]	Tauchert S R, Volkov M, Ehberger D, Kazenwadel D, Evers M, Lange H, Donges A, Book A, Kreuzpaintner W, Nowak U, Baum P 2022 Nature 602 73 Google Scholar
[74]	Ren Y, Zuo Y L, Si M S, Zhang Z Z, Jin Q Y, Zhou S M 2013 Ieee T. Magn. 49 3159 Google Scholar
[75]	Zhang Z, Wu D, Luan Z, Yuan H, Zhang Z, Zhao J, Zhao H, Chen L 2015 IEEE Magn. Lett. 6 1 Google Scholar
[76]	Woltersdorf G, Kiessling M, Meyer G, Thiele J U, Back C H 2009 Phys. Rev. Lett. 102 257602 Google Scholar
[77]	Gilmore K, Stiles M D, Seib J, Steiauf D, Fahnle M 2010 Phys. Rev. B 81 174414 Google Scholar
[78]	Xia H, Zhao Z R, Zeng F L, Zhao H C, Shi J Y, Zheng Z, Shen X, He J, Ni G, Wu Y Z, Chen L Y, Zhao H B 2021 Phys. Rev. B 104 024404 Google Scholar
[79]	Zhang W, He W, Zhang X Q, Cheng Z H, Teng J, Fähnle M 2017 Phys. Rev. B 96 220415 Google Scholar
[80]	Zhang W, Liu Q, Yuan Z, Xia K, He W, Zhan Q F, Zhang X Q, Cheng Z H 2019 Phys. Rev. B 100 104412 Google Scholar
[81]	Unikandanunni V, Medapalli R, Fullerton E E, Carva K, Oppeneer P M, Bonetti S 2021 Appl. Phys. Lett. 118 232404 Google Scholar
[82]	Yang X, Qiu L, Li Y, Xue H P, Liu J N, Sun R, Yang Q L, Gai X S, Wei Y S, Comstock A H, Sun D, Zhang X Q, He W, Hou Y, Cheng Z H 2023 Phys. Rev. Lett. 131 186703 Google Scholar
[83]	Waldrop M M 2016 Nature 530 144 Google Scholar
[84]	Goulielmakis E, Schultze M, Hofstetter M, Yakovlev V S, Gagnon J, Uiberacker M, Aquila A L, Gullikson E M, Attwood D T, Kienberger R, Krausz F, Kleineberg U 2008 Science 320 1614 Google Scholar
[85]	Gaumnitz T, Jain A, Pertot Y, Huppert M, Jordan I, Ardana-Lamas F, Worner H J 2017 Opt. Express 25 27506 Google Scholar
[86]	Zhao K, Zhang Q, Chini M, Wu Y, Wang X, Chang Z 2012 Opt. Lett. 37 3891 Google Scholar
[87]	Midorikawa K 2022 Nat. Photonics 16 267 Google Scholar
[88]	Xue B, Tamaru Y, Fu Y, Yuan H, Lan P, Mücke O D, Suda A, Midorikawa K, Takahashi E J 2020 Sci. Adv. 6 eaay2802 Google Scholar
[89]	Ferrari F, Calegari F, Lucchini M, Vozzi C, Stagira S, Sansone G, Nisoli M 2010 Nat. Photonics 4 875 Google Scholar
[90]	Corkum P B, Krausz F 2007 Nat. Phys. 3 381 Google Scholar
[91]	Popmintchev T, Chen M C, Arpin P, Murnane M M, Kapteyn H C 2010 Nat. Photonics 4 822 Google Scholar
[92]	Popmintchev T, Chen M C, Popmintchev D, Arpin P, Brown S, Ališauskas S, Andriukaitis G, Balčiunas T, Mücke O D, Pugzlys A, Baltuška A, Shim B, Schrauth S E, Gaeta A, Hernández-García C, Plaja L, Becker A, Jaron-Becker A, Murnane M M, Kapteyn H C 2012 Science 336 1287 Google Scholar
[93]	Li S, Wang R, Frauenheim T, He J 2024 J. Phys. Chem. Lett. 15 5959 Google Scholar
[94]	Tao Z, Chen C, Szilvási T, Keller M, Mavrikakis M, Kapteyn H, Murnane M 2016 Science 353 62 Google Scholar
[95]	Hofherr M, Häuser S, Dewhurst J K, Tengdin P, Sakshath S, Nembach H T, Weber S T, Shaw J M, Silva T J, Kapteyn H C, Cinchetti M, Rethfeld B, Murnane M M, Steil D, Stadtmüller B, Sharma S, Aeschlimann M, Mathias S 2020 Sci. Adv. 6 eaay8717 Google Scholar
[96]	Ryan S a A, Johnsen P C, Elhanoty M F, Grafov A, Li N, Delin A, Markou A, Lesne E, Felser C, Eriksson O, Kapteyn H C, Grånäs O, Murnane M M 2023 Sci. Adv. 9 eadi1428 Google Scholar
[97]	Tengdin P, Gentry C, Blonsky A, Zusin D, Gerrity M, Hellbrück L, Hofherr M, Shaw J, Kvashnin Y, Delczeg-Czirjak E K, Arora M, Nembach H, Silva T J, Mathias S, Aeschlimann M, Kapteyn H C, Thonig D, Koumpouras K, Eriksson O, Murnane M M 2020 Sci. Adv. 6 eaaz1100 Google Scholar
[98]	Locher R, Castiglioni L, Lucchini M, Greif M, Gallmann L, Osterwalder J, Hengsberger M, Keller U 2015 Optica 2 405 Google Scholar
[99]	Krausz F, Ivanov M 2009 Rev. Mod. Phys. 81 163 Google Scholar
[100]	Chainani A, Yokoya T, Kiss T, Shin S 2000 Phys. Rev. Lett. 85 1966 Google Scholar
[101]	Bigot J Y, Vomir M, Beaurepaire E 2009 Nat. Phys. 5 515 Google Scholar

施引文献

图 1 超快自旋动力学不同时间区域　(a) Ni薄膜的超快退磁现象^[5]; (b) 超快自旋动力学3个过程, I为超快退磁, II为磁矩恢复, III为磁矩进动^[32]; (c) 激光与铁磁性金属相互作用的热力学库; (d) Ni的三温度模型得到的电子、晶格、自旋的温度变化^[5]

Fig. 1. Different time regimes of the ultrafast spin dynamics: (a) The ultrafast demagnetization of Ni thin film^[5]; (b) the three-time regimes of Fe/MgO, I represents ultrafast demagnetization, II represents magnetic moment recovery, and III represents magnetic moment precession^[32]; (c) the interaction between the laser pulse and the three thermalized reservoirs of electrons, lattice, and spin; (d) the temperature changes of electrons, lattice, and spin with time^[5].

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图 2 拓扑表面态增强的Fe/Bi₂Se₃的超快自旋动力学行为　(a), (b)分别为9 QL和3 QL的Bi₂Se₃能带结构; (c) 异质结阻尼因子随温度的变化; (d) Fe/Bi₂Se₃ (9 QL 和3 QL)表面态对超快退磁的影响^[57]

Fig. 2. Topological surface state enhanced ultrafast spin dynamics of Fe/Bi₂Se₃ heterostructures: (a), (b) The band structures of Bi₂Se₃ with the thickness of 9 QL and 3 QL; (c) temperature dependence of damping; (d) ultrafast demagnetization curves of different samples^[57].

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图 3 可产生Skyrmions的FeGe材料中Type I-Type II超快退磁的转变　(a), (b) 分别为温度、磁场相关的FeGe薄膜的超快退磁行为; (c), (d)分别为第1步退磁与第2步退磁的退磁时间、退磁量的比值, 其中(c)插图为50 ps内的示例曲线; (e), (f)分别为磁性测量的FeGe磁相图, 灰色线为磁相转变区, 椭圆形区域为Skyrmions出现区域, 不同的颜色代表(c)和(d)的数值, 白色虚线为Type I到Type II转变的边界, 黑色点为测量TR-MOKE的条件, 红色点为(a)和(b)的测量条件^[59]

Fig. 3. Transition of Type I-Type II ultrafast demagnetization in FeGe materials capable of generating Skyrmions. (a), (b) The dependence of the ultrafast demagnetization of FeGe film on the ambient temperature scenario and field scenario. (c), (d) The demagnetization times and amplitude ratios between the second and first step obtained by bi-exponential function. Inset in (c) is an example curve shown up to 50 ps. (e), (f) The magnetic phase diagrams of FeGe obtained by magnetization measurements. Gray solid lines are the boundaries of magnetic phases. Elliptic shadow is a reference skyrmion region. Color map in (e), (f) represents the data in (c), (d), respectively. The white dashed line is the boundary between Type-I and Type-II demagnetization. Black dots are all the TR-MOKE measurement points; red dots are the data points shown in (a), (b)^[59].

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图 4 圆偏振的飞秒激光脉冲全光学磁记录^[6]

Fig. 4. All-optical magnetic recording by the circular femtosecond laser pulse^[6].

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图 5 (a)超快激光脉冲激发下基于逆Rashba-Edelstein效应的太赫兹发射原理图^[27]; (b) Fe/Ag/Bi薄膜的频域太赫兹信号^[27]

Fig. 5. (a) Schematic of THz emission via inverse Rashba-Edelstein effect upon excitation of ultrafast laser pulses^[27]; (b) the frequency-domain THz signal of Fe/Ag/Bi^[27].

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图 6 费米面呼吸以及冒泡模型　(a)描述不同时刻的费米面的形状, 费米面呼吸膜型; (b) 带间跃迁和带内跃迁^[77]

Fig. 6. Fermi surface breathing model and bubbling model: (a) A sketch of the Fermi surface at different times; (b) the intraband and interband transition^[77].

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图 7 超快退磁时间与阻尼因子的关系　(a) Co/Ni双层膜的超快退磁时间与阻尼因子的正比关系^[79]; (b) FeGa/IrMn双层膜的超快退磁时间与阻尼因子的反比关系^[80]

Fig. 7. Relationship between the ultrafast demagnetization time and damping: (a) The ultrafast demagnetization time is in direct proportion to the damping in the Co/Ni bilayer^[79]; (b) the ultrafast demagnetization time is inversely proportional to the damping in the FeGa/IrMn bilayer^[80].

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图 8 (a) Co薄膜中的各向异性超快自旋动力学^[81]; (b), (c) Fe/GeTe (30 nm)的各向异性阻尼因子与各向异性能带结构; (d), (e) Fe/GeTe (5 nm)的各向同性阻尼因子以及各向同性的能带劈裂^[82]

Fig. 8. (a) Anisotropic ultrafast spin dynamics in Co thin film^[81]; (b), (c) the anisotropic damping and splitting band structures of Fe/GeTe (30 nm); (d), (e) the isotropic damping and band structure of Fe/GeTe (5 nm)^[82].

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图 9 高次谐波的准经典三步模型^[90]

Fig. 9. Quasi-classical three-step model of higher harmonics^[90]

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图 10 RABBITT方法实现阿秒时间分辨的电子动力学　(a)利用RABBITT实现阿秒时间分辨的光电子能谱装置^[98]; (b) RABBITT的过程示意图^[98]

Fig. 10. Attosecond time resolution electrons dynamics by RABBITT method: (a) Schematic illustration of the photoemission spectrum with attosecond time resolution by RABBITT method^[98]; (b) schematic representation of the three steps of RABBITT^[98].

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图 11 高次谐波的典型特征

Fig. 11. Typical character of the high Harmonic generation.

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表 1 常见的3d过度族元素的M_{2, 3}边的能量

Table 1. The M_{2, 3} energies for 3d elements.

元素 M_{2, 3} 边能量/eV 元素 M_{2, 3} 边能量/eV

Sc 32 Fe 54
Ti 35 Co 60
V 38 Ni 68
Cr 42 Cu 74
Mn 49 Zn 87

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[1]	Kirilyuk A, Kimel A V, Rasing T 2010 Rev. Mod. Phys. 82 2731 Google Scholar
[2]	Walowski J, Münzenberg M 2016 J. Appl. Phys. 120 140901 Google Scholar
[3]	Farle M 1998 Rep. Prog. Phys. 61 755 Google Scholar
[4]	Kambersky V 1976 Czech. J. Phys. B 26 1366 Google Scholar
[5]	Beaurepaire E, Merle J C, Daunois A, Bigot J Y 1996 Phys. Rev. Lett. 76 4250 Google Scholar
[6]	Stanciu C D, Hansteen F, Kimel A V, Kirilyuk A, Tsukamoto A, Itoh A, Rasing T 2007 Phys. Rev. Lett. 99 047601 Google Scholar
[7]	Lambert C H, Mangin S, Varaprasad B S D C S, Takahashi Y K, Hehn M, Cinchetti M, Malinowski G, Hono K, Fainman Y, Aeschlimann M, Fullerton E E 2014 Science 345 1337 Google Scholar
[8]	Igarashi J, Zhang W, Remy Q, Diaz E, Lin J X, Hohlfeld J, Hehn M, Mangin S, Gorchon J, Malinowski G 2023 Nat. Mater. 22 725 Google Scholar
[9]	Huisman T J, Mikhaylovskiy R V, Costa J D, Freimuth F, Paz E, Ventura J, Freitas P P, Blugel S, Mokrousov Y, Rasing T, Kimel A V 2016 Nat. Nanotechnol. 11 455 Google Scholar
[10]	McPherson A, Gibson G, Jara H, Johann U, Luk T S, McIntyre I A, Boyer K, Rhodes C K 1987 J. Opt. Soc. Am. B 4 595 Google Scholar
[11]	Ferray M, L'Huillier A, Li X F, Lomprk L A, Mainfray G, Manus C 1988 J. Phys. B-At. Mol. Opt. 21 L31 Google Scholar
[12]	Nisoli M, Sansone G 2009 Prog. Quant. Electron. 33 17 Google Scholar
[13]	Siegrist F, Gessner J A, Ossiander M, Denker C, Chang Y P, Schroder M C, Guggenmos A, Cui Y, Walowski J, Martens U, Dewhurst J K, Kleineberg U, Munzenberg M, Sharma S, Schultze M 2019 Nature 571 240 Google Scholar
[14]	Li Y, Li Y, Liu Q, Xie Z K, Vetter E, Yuan Z, He W, Liu H L, Sun D L, Xia K, Yu W, Sun Y B, Zhao J J, Zhang X Q, Cheng Z H 2019 New J. Phys. 21 103040 Google Scholar
[15]	Tserkovnyak Y, Brataas A, Bauer G E 2002 Phys. Rev. Lett. 88 117601 Google Scholar
[16]	Katine J A, Albert F J, Buhrman R A 2000 Phys. Rev. Lett. 84 3149 Google Scholar
[17]	Ralph D C, Stiles M D 2008 J. Magn. Magn. Mater. 320 1190 Google Scholar
[18]	Soumyanarayanan A, Reyren N, Fert A, Panagopoulos C 2016 Nature 539 509 Google Scholar
[19]	Xiao D, Chang M C, Niu Q 2010 Rev. Mod. Phys. 82 1959 Google Scholar
[20]	Yang S A 2016 Spin 06 1640003 Google Scholar
[21]	Chen Y L, Analytis J G, Chu J H, Liu Z K, Mo S K, Qi X L, Zhang H J, Lu D H, Dai X, Fang Z, Zhang S C, Fisher I R, Hussain Z, Shen Z X 2009 Science 325 178 Google Scholar
[22]	Di Sante D, Barone P, Bertacco R, Picozzi S 2013 Adv. Mater. 25 509 Google Scholar
[23]	Manchon A, Koo H C, Nitta J, Frolov S M, Duine R A 2015 Nat. Mater. 14 871 Google Scholar
[24]	Sinova J, Valenzuela S O, Wunderlich J, Back C H, Jungwirth T 2015 Rev Mod Phys 87 1213 Google Scholar
[25]	Neubauer A, Pfleiderer C, Binz B, Rosch A, Ritz R, Niklowitz P G, Boni P 2009 Phys. Rev. Lett. 102 186602 Google Scholar
[26]	Yu X Z, Kanazawa N, Onose Y, Kimoto K, Zhang W Z, Ishiwata S, Matsui Y, Tokura Y 2011 Nat. Mater. 10 106 Google Scholar
[27]	Zhou C, Liu Y P, Wang Z, Ma S J, Jia M W, Wu R Q, Zhou L, Zhang W, Liu M K, Wu Y Z, Qi J 2018 Phys. Rev. Lett. 121 086801 Google Scholar
[28]	Zutic I, Fabian J, Das Sarma S 2004 Rev. Mod. Phys. 76 323 Google Scholar
[29]	Baibich M N, Broto J M, Fert A, Nguyen Van Dau F, Petroff F, Etienne P, Creuzet G, Friederich A, Chazelas J 1988 Phys. Rev. Lett. 61 2472 Google Scholar
[30]	Binasch G, Grunberg P, Saurenbach F, Zinn W 1989 Phys. Rev. B Condens. Matter. 39 4828 Google Scholar
[31]	Hashimoto S, Ochiai Y 1990 J. Magn. Magn. Mater. 88 211 Google Scholar
[32]	Cheng Z H, He W, Zhang X Q, Sun D L, Du H F, Wu Q, Ye J, Fang Y P, Liu H L 2015 Chin. Phys. B 24 077505 Google Scholar
[33]	Walowski J, Muller G, Djordjevic M, Munzenberg M, Klaui M, Vaz C A, Bland J A 2008 Phys. Rev. Lett. 101 237401 Google Scholar
[34]	Radu I, Woltersdorf G, Kiessling M, Melnikov A, Bovensiepen U, Thiele J U, Back C H 2009 Phys. Rev. Lett. 102 117201 Google Scholar
[35]	Guidoni L, Beaurepaire E, Bigot J Y 2002 Phys. Rev. Lett. 89 017401 Google Scholar
[36]	Graves C E, Reid A H, Wang T, et al. 2013 Nat. Mater. 12 293 Google Scholar
[37]	Bartelt A F, Comin A, Feng J, Nasiatka J R, Eimüller T, Ludescher B, Schütz G, Padmore H A, Young A T, Scholl A 2007 Appl. Phys. Lett. 90 162503 Google Scholar
[38]	Li Y, Zhang W, Li N, Sun R, Tang J, Gong Z Z, Li Y, Yang X, Xie Z K, Gul Q, Zhang X Q, He W, Cheng Z H 2019 J. Phys. Condens. Mat. 31 305802 Google Scholar
[39]	Zhang Q, Nurmikko A V, Miao G X, Xiao G, Gupta A 2006 Phys. Rev. B 74 064414 Google Scholar
[40]	Muller G M, Walowski J, Djordjevic M, Miao G X, Gupta A, Ramos A V, Gehrke K, Moshnyaga V, Samwer K, Schmalhorst J, Thomas A, Hutten A, Reiss G, Moodera J S, Munzenberg M 2009 Nat. Mater. 8 56 Google Scholar
[41]	Lu X Y, Lin Z Y, Pi H Q, Zhang T, Li G Q, Gong Y T, Yan Y, Ruan X Z, Li Y, Zhang H, Li L, He L, Wu J, Zhang R, Weng H M, Zeng C G, Xu Y B 2024 Nat. Commun. 15 2410 Google Scholar
[42]	Lichtenberg T, Schippers C F, van Kooten S C P, Evers S G F, Barcones B, Guimarães M H D, Koopmans B 2022 2D Mater. 10 015008 Google Scholar
[43]	Wu N, Zhang S J, Chen D Q, Wang Y X, Meng S 2024 Nat. Commun. 15 2804 Google Scholar
[44]	Khela M, Da Browski M, Khan S, Keatley P S, Verzhbitskiy I, Eda G, Hicken R J, Kurebayashi H, Santos E J G 2023 Nat. Commun. 14 1378 Google Scholar
[45]	Sun T, Zhou C, Jiang Z Z, Li X M, Qiu K, Xiao R C, Liu C X, Ma Z W, Luo X, Sun Y P, Sheng Z G 2021 2D Mater. 8 045040 Google Scholar
[46]	Da Browski M, Guo S, Strungaru M, Keatley P S, Withers F, Santos E J G, Hicken R J 2022 Nat. Commun. 13 5976 Google Scholar
[47]	Lee W J, Fernandez-Mulligan S, Tan H X, Yan C H, Guan Y D, Lee S H, Mei R B, Liu C X, Yan B H, Mao Z Q, Yang S L 2023 Nat. Phys. 19 950 Google Scholar
[48]	Padmanabhan H, Stoica V A, Kim P K, Poore M, Yang T N, Shen X Z, Reid A H, Lin M F, Park S, Yang J, Wang H Y, Koocher N Z, Puggioni D, Georgescu A B, Min L J, Lee S H, Mao Z Q, Rondinelli J M, Lindenberg A M, Chen L Q, Wang X J, Averitt R D, Freeland J W, Gopalan V 2022 Adv. Mater. 34 2202841 Google Scholar
[49]	Bartram F M, Leng Y C, Wang Y, Liu L, Chen X, Peng H, Li H, Yu P, Wu Y, Lin M L, Zhang J, Tan P H, Yang L 2022 npj Quantum. Mater. 7 84 Google Scholar
[50]	Evans R F L, Fan W J, Chureemart P, Ostler T A, Ellis M O A, Chantrell R W 2014 J. Phys. Condens. Matter. 26 103202 Google Scholar
[51]	Atxitia U, Chubykalo-Fesenko O 2011 Phys. Rev. B 84 144414 Google Scholar
[52]	Koopmans B, Ruigrok J J, Longa F D, de Jonge W J 2005 Phys. Rev. Lett. 95 267207 Google Scholar
[53]	Koopmans B, Malinowski G, Dalla Longa F, Steiauf D, Fahnle M, Roth T, Cinchetti M, Aeschlimann M 2010 Nat. Mater. 9 259 Google Scholar
[54]	Battiato M, Carva K, Oppeneer P M 2010 Phys. Rev. Lett. 105 027203 Google Scholar
[55]	Malinowski G, Dalla Longa F, Rietjens J H H, Paluskar P V, Huijink R, Swagten H J M, Koopmans B 2008 Nat. Phys. 4 855 Google Scholar
[56]	Schellekens A J, Kuiper K C, de Wit R R J C, Koopmans B 2014 Nat. Commun. 5 4333 Google Scholar
[57]	Li N, Sun Y B, Sun R, Yang X, Zhang W, Xie Z K, Liu J N, Li Y, Li Y, Gong Z Z, Zhang X Q, He W, Cheng Z H 2022 Phys. Rev. B 105 144415 Google Scholar
[58]	Hou Y S, Wu R Q 2019 Phys. Rev. Appl. 11 054032 Google Scholar
[59]	Gong Z H, Zhang W, Liu J N, Xie Z K, Yang X, Tang J, Du H F, Li N, Zhang X Q, He W, Cheng Z H 2023 Phys. Rev. B 107 144429 Google Scholar
[60]	Zhang X C, Shkurinov A, Zhang Y 2017 Nat. Photonics 11 16 Google Scholar
[61]	Pawar A Y, Sonawane D D, Erande K B, Derle D V 2013 Drug. Invent. Today 5 157 Google Scholar
[62]	Kampfrath T, Battiato M, Maldonado P, Eilers G, Notzold J, Mahrlein S, Zbarsky V, Freimuth F, Mokrousov Y, Blugel S, Wolf M, Radu I, Oppeneer P M, Munzenberg M 2013 Nat. Nanotechnol. 8 256 Google Scholar
[63]	Hirsch J E 1999 Phys. Rev. Lett. 83 1834 Google Scholar
[64]	Kato Y K, Myers R C, Gossard A C, Awschalom D D 2004 Science 306 1910 Google Scholar
[65]	Ando K, Takahashi S, Harii K, Sasage K, Ieda J, Maekawa S, Saitoh E 2008 Phys. Rev. Lett. 101 036601 Google Scholar
[66]	Rojas-Sanchez J C, Reyren N, Laczkowski P, Savero W, Attane J P, Deranlot C, Jamet M, George J M, Vila L, Jaffres H 2014 Phys. Rev. Lett. 112 106602 Google Scholar
[67]	Sun R, Yang S J, Yang X, Vetter E, Sun D L, Li N, Su L, Li Y, Li Y, Gong Z Z, Xie Z K, Hou K Y, Gul Q, He W, Zhang X Q, Cheng Z H 2019 Nano Lett. 19 4420 Google Scholar
[68]	Sun R, Yang S J, Yang X, Kumar A, Vetter E, Xue W H, Li Y, Li N, Li Y, Zhang S H, Ge B H, Zhang X Q, He W, Kemper A F, Sun D, Cheng Z H 2020 Adv. Mater. 32 2005315 Google Scholar
[69]	Qiu H S, Zhou L, Zhang C, Wu J, Tian Y, Cheng S, Mi S, Zhao H, Zhang Q, Wu D, Jin B, Chen J, Wu P 2020 Nat. Phys. 17 388 Google Scholar
[70]	Tang J, Ke Y J, He W, Zhang X Q, Zhang W, Li N, Zhang Y S, Li Y, Cheng Z H 2018 Adv. Mater. 30 1706439 Google Scholar
[71]	Kuiper K C, Roth T, Schellekens A J, Schmitt O, Koopmans B, Cinchetti M, Aeschlimann M 2014 Appl. Phys. Lett. 105 202402 Google Scholar
[72]	Zhang G P, Hubner W 2000 Phys. Rev. Lett. 85 3025 Google Scholar
[73]	Tauchert S R, Volkov M, Ehberger D, Kazenwadel D, Evers M, Lange H, Donges A, Book A, Kreuzpaintner W, Nowak U, Baum P 2022 Nature 602 73 Google Scholar
[74]	Ren Y, Zuo Y L, Si M S, Zhang Z Z, Jin Q Y, Zhou S M 2013 Ieee T. Magn. 49 3159 Google Scholar
[75]	Zhang Z, Wu D, Luan Z, Yuan H, Zhang Z, Zhao J, Zhao H, Chen L 2015 IEEE Magn. Lett. 6 1 Google Scholar
[76]	Woltersdorf G, Kiessling M, Meyer G, Thiele J U, Back C H 2009 Phys. Rev. Lett. 102 257602 Google Scholar
[77]	Gilmore K, Stiles M D, Seib J, Steiauf D, Fahnle M 2010 Phys. Rev. B 81 174414 Google Scholar
[78]	Xia H, Zhao Z R, Zeng F L, Zhao H C, Shi J Y, Zheng Z, Shen X, He J, Ni G, Wu Y Z, Chen L Y, Zhao H B 2021 Phys. Rev. B 104 024404 Google Scholar
[79]	Zhang W, He W, Zhang X Q, Cheng Z H, Teng J, Fähnle M 2017 Phys. Rev. B 96 220415 Google Scholar
[80]	Zhang W, Liu Q, Yuan Z, Xia K, He W, Zhan Q F, Zhang X Q, Cheng Z H 2019 Phys. Rev. B 100 104412 Google Scholar
[81]	Unikandanunni V, Medapalli R, Fullerton E E, Carva K, Oppeneer P M, Bonetti S 2021 Appl. Phys. Lett. 118 232404 Google Scholar
[82]	Yang X, Qiu L, Li Y, Xue H P, Liu J N, Sun R, Yang Q L, Gai X S, Wei Y S, Comstock A H, Sun D, Zhang X Q, He W, Hou Y, Cheng Z H 2023 Phys. Rev. Lett. 131 186703 Google Scholar
[83]	Waldrop M M 2016 Nature 530 144 Google Scholar
[84]	Goulielmakis E, Schultze M, Hofstetter M, Yakovlev V S, Gagnon J, Uiberacker M, Aquila A L, Gullikson E M, Attwood D T, Kienberger R, Krausz F, Kleineberg U 2008 Science 320 1614 Google Scholar
[85]	Gaumnitz T, Jain A, Pertot Y, Huppert M, Jordan I, Ardana-Lamas F, Worner H J 2017 Opt. Express 25 27506 Google Scholar
[86]	Zhao K, Zhang Q, Chini M, Wu Y, Wang X, Chang Z 2012 Opt. Lett. 37 3891 Google Scholar
[87]	Midorikawa K 2022 Nat. Photonics 16 267 Google Scholar
[88]	Xue B, Tamaru Y, Fu Y, Yuan H, Lan P, Mücke O D, Suda A, Midorikawa K, Takahashi E J 2020 Sci. Adv. 6 eaay2802 Google Scholar
[89]	Ferrari F, Calegari F, Lucchini M, Vozzi C, Stagira S, Sansone G, Nisoli M 2010 Nat. Photonics 4 875 Google Scholar
[90]	Corkum P B, Krausz F 2007 Nat. Phys. 3 381 Google Scholar
[91]	Popmintchev T, Chen M C, Arpin P, Murnane M M, Kapteyn H C 2010 Nat. Photonics 4 822 Google Scholar
[92]	Popmintchev T, Chen M C, Popmintchev D, Arpin P, Brown S, Ališauskas S, Andriukaitis G, Balčiunas T, Mücke O D, Pugzlys A, Baltuška A, Shim B, Schrauth S E, Gaeta A, Hernández-García C, Plaja L, Becker A, Jaron-Becker A, Murnane M M, Kapteyn H C 2012 Science 336 1287 Google Scholar
[93]	Li S, Wang R, Frauenheim T, He J 2024 J. Phys. Chem. Lett. 15 5959 Google Scholar
[94]	Tao Z, Chen C, Szilvási T, Keller M, Mavrikakis M, Kapteyn H, Murnane M 2016 Science 353 62 Google Scholar
[95]	Hofherr M, Häuser S, Dewhurst J K, Tengdin P, Sakshath S, Nembach H T, Weber S T, Shaw J M, Silva T J, Kapteyn H C, Cinchetti M, Rethfeld B, Murnane M M, Steil D, Stadtmüller B, Sharma S, Aeschlimann M, Mathias S 2020 Sci. Adv. 6 eaay8717 Google Scholar
[96]	Ryan S a A, Johnsen P C, Elhanoty M F, Grafov A, Li N, Delin A, Markou A, Lesne E, Felser C, Eriksson O, Kapteyn H C, Grånäs O, Murnane M M 2023 Sci. Adv. 9 eadi1428 Google Scholar
[97]	Tengdin P, Gentry C, Blonsky A, Zusin D, Gerrity M, Hellbrück L, Hofherr M, Shaw J, Kvashnin Y, Delczeg-Czirjak E K, Arora M, Nembach H, Silva T J, Mathias S, Aeschlimann M, Kapteyn H C, Thonig D, Koumpouras K, Eriksson O, Murnane M M 2020 Sci. Adv. 6 eaaz1100 Google Scholar
[98]	Locher R, Castiglioni L, Lucchini M, Greif M, Gallmann L, Osterwalder J, Hengsberger M, Keller U 2015 Optica 2 405 Google Scholar
[99]	Krausz F, Ivanov M 2009 Rev. Mod. Phys. 81 163 Google Scholar
[100]	Chainani A, Yokoya T, Kiss T, Shin S 2000 Phys. Rev. Lett. 85 1966 Google Scholar
[101]	Bigot J Y, Vomir M, Beaurepaire E 2009 Nat. Phys. 5 515 Google Scholar

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超快自旋动力学: 从飞秒磁学到阿秒磁学