Journal
ACS PHOTONICS
Volume 5, Issue 4, Pages 1375-1380Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acsphotonics.7b01402
Keywords
polaritonics; magnonics; terahertz spectroscopy; antiferromagnetism; ultrafast dynamics
Categories
Funding
- National Natural Science Foundation of China (NSFC) [11674213, 11604202, 61735010, 51372149]
- European Research Council ERC Grant [339813]
- NWO (The Netherlands Organization for Scientific Research)
- Young Eastern Scholar at Shanghai Institutions of Higher Learning [QD2015020]
- Universities Young Teachers Training Funding Program [ZZSD15098]
- Chen Guang project [16CG45]
- Russian Science Foundation [16-12-10520]
- Ministry of Education and Science of the Russian Federation [14.Z50.31.0034]
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Magnon-polaritons are shown to play a dominant role in the propagation of terahertz(THz) waves through TmFeO3 orthoferrite, if the frequencies of the waves are in the vicinity of the quasi-antiferromagnetic spin resonance mode. Both time-domain THz transmission and emission spectroscopies reveal clear beatings between two modes with frequencies slightly above and slightly below this resonance, respectively. Rigorous modeling of the interaction between the spins of TmFeO3 and the THz light shows that the frequencies correspond to the upper and lower magnon-polariton branches. Our findings reveal the previously ignored importance of propagation effects and polaritons in such heavily debated areas as THz magnonics and THz spectroscopy of electromagnons. It also shows that future progress in these areas calls for an interdisciplinary approach at the interface between magnetism and photonics.
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