Engineered quantum Hall samples with tunable counter-propagating channels exhibit ballistic transport for unequal up- and downstream numbers and a diffusive regime with diverging equilibration length when numbers match.
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A driven dipole-conserving Bose-Hubbard model realizes controllable resonant splitting and motion of dipoles and fractons via engineered time-dependent tensor electric fields.
Reinforcement fine-tuning of a generative model produces new topological insulators and crystalline insulators, exemplified by Ge2Bi2O6 with a 0.26 eV full band gap.
citing papers explorer
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Ballistic-to-diffusive transition in engineered counter-propagating quantum Hall channels
Engineered quantum Hall samples with tunable counter-propagating channels exhibit ballistic transport for unequal up- and downstream numbers and a diffusive regime with diverging equilibration length when numbers match.
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Resonant dynamics of dipole-conserving Bose-Hubbard model with time-dependent tensor electric fields
A driven dipole-conserving Bose-Hubbard model realizes controllable resonant splitting and motion of dipoles and fractons via engineered time-dependent tensor electric fields.
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Design Topological Materials by Reinforcement Fine-Tuned Generative Model
Reinforcement fine-tuning of a generative model produces new topological insulators and crystalline insulators, exemplified by Ge2Bi2O6 with a 0.26 eV full band gap.