Coherent spin-wave transport in an antiferromagnet

Magnonics is a research field complementary to spintronics, in which the quanta of spin waves (magnons) replace electrons as information carriers, promising lower dissipation(1-3). The development of ultrafast, nanoscale magnonic logic circuits calls for new tools and materials to generate coherent spin waves with frequencies as high and wavelengths as short as possible(4,5). Antiferromagnets can host spin waves at terahertz frequencies and are therefore seen as a future platform for the fastest and least dissipative transfer of information(6-11). However, the generation of short-wavelength coherent propagating magnons in antiferromagnets has so far remained elusive. Here we report the efficient emission and detection of a nanometre-scale wavepacket of coherent propagating magnons in the antiferromagnetic oxide dysprosium orthoferrite using ultrashort pulses of light. The subwavelength confinement of the laser field due to large absorption creates a strongly non-uniform spin excitation profile, enabling the propagation of a broadband continuum of coherent terahertz spin waves. The wavepacket contains magnons with a shortest detected wavelength of 125 nm that propagate into the material with supersonic velocities of more than 13 km s(-1). This source of coherent short-wavelength spin carriers opens up new prospects for terahertz antiferromagnetic magnonics and coherence-mediated logic devices at terahertz frequencies.

Automated summary

Magnonics is a research field focusing on utilizing spin waves as information carriers instead of electrons to reduce energy dissipation. Researchers have successfully achieved efficient emission and detection of nanometer-scale wavepacket of coherent propagating magnons in antiferromagnetic oxide dysprosium orthoferrite, paving the way for terahertz antiferromagnetic magnonics and coherence-mediated logic devices at terahertz frequencies.