Femtosecond switching of magnetism via strongly correlated spin–charge quantum excitations

Autor: Leonidas Mouchliadis, Ilias E. Perakis, Tianqi Li, Aaron Patz, Jigang Wang, Jiaqiang Yan, Thomas A. Lograsso
Rok vydání: 2013
Předmět:
Zdroj: Nature. 496:69-73
ISSN: 1476-4687
0028-0836
DOI: 10.1038/nature11934
Popis: Magnetic order in a manganite can be switched during femtosecond photo-excitation via coherent superpositions of quantum states; this is analogous to processes in femtosecond chemistry where photoproducts of chemical and biochemical reactions can be influenced by creating suitable superpositions of molecular states. Today's magnetic memory and logic devices operate at gigahertz switching speeds. To achieve the even faster terahertz regime will require new technologies, and ultrafast all-optical magnetic switching using coherent spin manipulation is a leading contender. Ilias Perakis and colleagues demonstrate a development of this technique that achieves femtosecond all-optical switching of the magnetic state through the establishment of a 'colossal' magnetization component from an antiferromagnetic ground state. The switch to ferromagnetic ordering in Pr0.7Ca0.3MnO3 occurs within a mere 120 femtoseconds, a remarkably short time interval for a non-equilibrium magnetic phase transition. This is a new principle in magnetic switching, analogous to processes in femtochemistryin which photoproducts of chemical and biochemical reactions can be influenced by creating suitable superpositions of molecular states. This work is also of relevance to the fields of spin-chemistry, quantum biology and spin-electronics. The technological demand to push the gigahertz (109 hertz) switching speed limit of today’s magnetic memory and logic devices into the terahertz (1012 hertz) regime underlies the entire field of spin-electronics and integrated multi-functional devices. This challenge is met by all-optical magnetic switching based on coherent spin manipulation1. By analogy to femtosecond chemistry and photosynthetic dynamics2—in which photoproducts of chemical and biochemical reactions can be influenced by creating suitable superpositions of molecular states—femtosecond-laser-excited coherence between electronic states can switch magnetic order by ‘suddenly’ breaking the delicate balance between competing phases of correlated materials: for example, manganites exhibiting colossal magneto-resistance suitable for applications3,4. Here we show femtosecond (10−15 seconds) photo-induced switching from antiferromagnetic to ferromagnetic ordering in Pr0.7Ca0.3MnO3, by observing the establishment (within about 120 femtoseconds) of a huge temperature-dependent magnetization with photo-excitation threshold behaviour absent in the optical reflectivity. The development of ferromagnetic correlations during the femtosecond laser pulse reveals an initial quantum coherent regime of magnetism, distinguished from the picosecond (10−12 seconds) lattice-heating regime characterized by phase separation without threshold behaviour5,6. Our simulations reproduce the nonlinear femtosecond spin generation and underpin fast quantum spin-flip fluctuations correlated with coherent superpositions of electronic states to initiate local ferromagnetic correlations. These results merge two fields, femtosecond magnetism in metals and band insulators1,7,8,9, and non-equilibrium phase transitions of strongly correlated electrons10,11,12,13,14,15,16,17, in which local interactions exceeding the kinetic energy produce a complex balance of competing orders.
Databáze: OpenAIRE
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