Holographic isoTNS represent volume-law entangled states including arbitrary fermionic Gaussian states, Clifford states, and certain short-time evolved states using an extra network dimension with isometric constraints.
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Localized Zhang-Rice singlets from doped holes generate emergent J2 and J3 superexchanges that produce magnetic frustration, collapsing Néel order and driving spin-glass behavior on the hole-doped side of cuprates.
Quantum calculations on an ab initio-parametrized Heisenberg model for hematite give a closer match to the experimental low-temperature spin-flop field than classical approximations.
citing papers explorer
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Holographic Representation of One-Dimensional Many-Body Quantum States via Isometric Tensor Networks
Holographic isoTNS represent volume-law entangled states including arbitrary fermionic Gaussian states, Clifford states, and certain short-time evolved states using an extra network dimension with isometric constraints.
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Frustration from Localized Zhang-Rice States: A Unified Theory of Doping-Driven Magnetic Transitions in Cuprates
Localized Zhang-Rice singlets from doped holes generate emergent J2 and J3 superexchanges that produce magnetic frustration, collapsing Néel order and driving spin-glass behavior on the hole-doped side of cuprates.
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Quantum fluctuations determine the spin-flop transition in hematite
Quantum calculations on an ab initio-parametrized Heisenberg model for hematite give a closer match to the experimental low-temperature spin-flop field than classical approximations.