Nature Communications (Jun 2024)

Terahertz photon to dc current conversion via magnetic excitations of multiferroics

  • Makiko Ogino,
  • Yoshihiro Okamura,
  • Kosuke Fujiwara,
  • Takahiro Morimoto,
  • Naoto Nagaosa,
  • Yoshio Kaneko,
  • Yoshinori Tokura,
  • Youtarou Takahashi

DOI
https://doi.org/10.1038/s41467-024-49056-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 7

Abstract

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Abstract Direct conversion from terahertz photon to charge current is a key phenomenon for terahertz photonics. Quantum geometrical description of optical processes in crystalline solids predicts existence of field-unbiased dc photocurrent arising from terahertz-light generation of magnetic excitations in multiferroics, potentially leading to fast and energy-efficient terahertz devices. Here, we demonstrate the dc charge current generation from terahertz magnetic excitations in multiferroic perovskite manganites with spin-driven ferroelectricity, while keeping an insulating state with no free carrier. It is also revealed that electromagnon, which ranges sub-terahertz to 2 THz, as well as antiferromagnetic resonance shows the giant conversion efficiency. Polar asymmetry induced by the cycloidal spin order gives rise to this terahertz-photon-induced dc photocurrent, and no external magnetic and electric bias field are required for this conversion process. The observed phenomena are beyond the conventional photovoltaics in semi-classical regime and demonstrate the essential role of quantum geometrical aspect in low-energy optical processes. Our finding establishes a paradigm of terahertz photovoltaic phenomena, paving a way for terahertz photonic devices and energy harvesting.