This video is from Qiskit.
Monitored quantum circuits exhibit entanglement transitions at certain measurement rates. Such a transition separates phases characterized by how much information an observer can learn from the measurement outcomes. We study SU(2)-symmetric monitored quantum circuits, using exact numerics. Due to the symmetry’s non-Abelian nature, measuring qubit pairs allows for nontrivial entanglement scaling even in the measurement-only limit. We find a transition between a volume-law entangled phase and a critical phase whose diffusive purification dynamics emerge from the non-Abelian symmetry. Additionally, we identify a “spin-sharpening transition.” Across the transition, the rate at which measurements reveal information about the total spin quantum number changes parametrically with system size. We compliment the numerics with an effective statistical-mechanics model.
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- Source: https://www.franksworld.com/2023/09/25/monitored-quantum-circuits-with-noncommuting-conserved-quantities/?utm_source=rss&utm_medium=rss&utm_campaign=monitored-quantum-circuits-with-noncommuting-conserved-quantities
