Neural quantum states with a tailored 3D convolutional architecture simulate quench dynamics up to 1000 qubits and verify the 3D quantum Kibble-Zurek mechanism with RG-derived logarithmic corrections and data collapse.
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Magnetic cavity coupling renders H2 ground states metastable, inverts singlet-triplet gaps, and stabilizes exotic antiaromatic states in rings like H4 and C4H4 by preventing Jahn-Teller distortions.
The work extends a prior protocol to compare single-click and double-click entanglement generation between ions over hundreds of kilometers, showing that optimal choice depends on phase stability and interface efficiencies.
citing papers explorer
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Real-time Dynamics in 3D for up to 1000 Qubits with Neural Quantum States: Quenches and the Quantum Kibble--Zurek Mechanism
Neural quantum states with a tailored 3D convolutional architecture simulate quench dynamics up to 1000 qubits and verify the 3D quantum Kibble-Zurek mechanism with RG-derived logarithmic corrections and data collapse.
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Engineering molecular potential energy surfaces using magnetic cavity quantum electrodynamics
Magnetic cavity coupling renders H2 ground states metastable, inverts singlet-triplet gaps, and stabilizes exotic antiaromatic states in rings like H4 and C4H4 by preventing Jahn-Teller distortions.
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Single and Double-click High-Rate Entanglement Generation Between Distant Ions Using Multiplexed Atomic Ensembles
The work extends a prior protocol to compare single-click and double-click entanglement generation between ions over hundreds of kilometers, showing that optimal choice depends on phase stability and interface efficiencies.