Multiferroic-enabled magnetic exciton in 2D quantum entangled van der Waals antiferromagnet NiI2

Authors :: Son, Suhan
Lee, Youjin
Kim, Jae Ha
Kim, Beom Hyun
Kim, Chaebin
Na, Woongki
Ju, Hwiin
Park, Sudong
Nag, Abhishek
Zhou, Ke-Jin
Son, Young-Woo
Kim, Hyeongdo
Noh, Woo-Suk
Park, Jae-Hoon
Lee, Jong Seok
Cheong, Hyeonsik
Kim, Jae Hoon
Park, Je-Geun
Publication Year :: 2021
Abstract: Matter-light interaction is at the center of diverse research fields from quantum optics to condensed matter physics, opening new fields like laser physics. A magnetic exciton is one such rare example found in magnetic insulators. However, it is relatively rare to observe that external variables control matter-light interaction. Here, we report that the broken inversion symmetry of multiferroicity can act as an external knob enabling the magnetic exciton in van der Waals antiferromagnet NiI2. We further discover that this magnetic exciton arises from a transition between Zhang-Rice-triplet and Zhang-Rice-singlet's fundamentally quantum entangled states. This quantum entanglement produces an ultra-sharp optical exciton peak at 1.384 eV with a 5 meV linewidth. Our work demonstrates that NiI2 is two-dimensional magnetically ordered with an intrinsically quantum entangled ground state.<br />Comment: 26 pages, 10 figures. Accepted for publication in Advanced Materials

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