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Main Authors: Park, Bum Chul, Kim, Sung-Chul, Lee, Dae Beom, Kim, Young Kwang, Kim, Bomin, Rhim, Sonny H., Lee, Eunsoo, Hong, Yongju, Lee, Kwangyeol, Lee, Sang Hyun, Ma, Jessica, Sawczyk, Michal, Lu, Jun, Manassa, Jason, Agarwal, Nishkarsh, Hovden, Robert, Won, Sung Ok, Ko, Min Jun, Park, Minkyu, Cho, Jiung, Mao, Xiaoming, Sun, Kai, Kim, Young Keun, Kotov, Nicholas A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.12362
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author Park, Bum Chul
Kim, Sung-Chul
Lee, Dae Beom
Kim, Young Kwang
Kim, Bomin
Rhim, Sonny H.
Lee, Eunsoo
Hong, Yongju
Lee, Kwangyeol
Lee, Sang Hyun
Ma, Jessica
Sawczyk, Michal
Lu, Jun
Manassa, Jason
Agarwal, Nishkarsh
Hovden, Robert
Won, Sung Ok
Ko, Min Jun
Park, Minkyu
Cho, Jiung
Mao, Xiaoming
Sun, Kai
Kim, Young Keun
Kotov, Nicholas A.
author_facet Park, Bum Chul
Kim, Sung-Chul
Lee, Dae Beom
Kim, Young Kwang
Kim, Bomin
Rhim, Sonny H.
Lee, Eunsoo
Hong, Yongju
Lee, Kwangyeol
Lee, Sang Hyun
Ma, Jessica
Sawczyk, Michal
Lu, Jun
Manassa, Jason
Agarwal, Nishkarsh
Hovden, Robert
Won, Sung Ok
Ko, Min Jun
Park, Minkyu
Cho, Jiung
Mao, Xiaoming
Sun, Kai
Kim, Young Keun
Kotov, Nicholas A.
contents Chiral quantum magnets with spin-states separated by a large energy gap are technologically attractive but difficult to realize. Geometrically frustrated topological states with nanoscale chirality may offer a chemical pathway to such materials. However, room temperature spin misalignment, weakness of Dzyaloshinskii-Moriya interactions, and high energy requirements for lattice distortions set high physicochemical barriers for their realization. Here, we show that layered iron oxyhydroxides (LIOX) address these challenges due to chirality transfer from surface ligands into spin-states of dimerized FeO6 octahedra with zig-zag stacking. The intercalation of chiral amino acids induces angular displacements in the antiferromagnetic spin pairs with a helical coupling of magnetic moments along the screw axis of the zig-zag chains, or helical spin-ladders. Unlike other chiral magnets, the spin states in LIOX are chemically and optically accessible, they display strong optical resonances with helicity-matching photons and enable spin-selective charge transport. The static rather than dynamic polarization of spin ladders in LIOX makes them particularly suitable for catalysis. Room-temperature spin pairing, field-tunability, environmental robustness, and synthetic simplicity make LIOX and its intercalates a uniquely practical family of quantum magnets.
format Preprint
id arxiv_https___arxiv_org_abs_2508_12362
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Chiral quantum magnets with optically and catalytically active spin ladders
Park, Bum Chul
Kim, Sung-Chul
Lee, Dae Beom
Kim, Young Kwang
Kim, Bomin
Rhim, Sonny H.
Lee, Eunsoo
Hong, Yongju
Lee, Kwangyeol
Lee, Sang Hyun
Ma, Jessica
Sawczyk, Michal
Lu, Jun
Manassa, Jason
Agarwal, Nishkarsh
Hovden, Robert
Won, Sung Ok
Ko, Min Jun
Park, Minkyu
Cho, Jiung
Mao, Xiaoming
Sun, Kai
Kim, Young Keun
Kotov, Nicholas A.
Materials Science
Chiral quantum magnets with spin-states separated by a large energy gap are technologically attractive but difficult to realize. Geometrically frustrated topological states with nanoscale chirality may offer a chemical pathway to such materials. However, room temperature spin misalignment, weakness of Dzyaloshinskii-Moriya interactions, and high energy requirements for lattice distortions set high physicochemical barriers for their realization. Here, we show that layered iron oxyhydroxides (LIOX) address these challenges due to chirality transfer from surface ligands into spin-states of dimerized FeO6 octahedra with zig-zag stacking. The intercalation of chiral amino acids induces angular displacements in the antiferromagnetic spin pairs with a helical coupling of magnetic moments along the screw axis of the zig-zag chains, or helical spin-ladders. Unlike other chiral magnets, the spin states in LIOX are chemically and optically accessible, they display strong optical resonances with helicity-matching photons and enable spin-selective charge transport. The static rather than dynamic polarization of spin ladders in LIOX makes them particularly suitable for catalysis. Room-temperature spin pairing, field-tunability, environmental robustness, and synthetic simplicity make LIOX and its intercalates a uniquely practical family of quantum magnets.
title Chiral quantum magnets with optically and catalytically active spin ladders
topic Materials Science
url https://arxiv.org/abs/2508.12362