Entanglement transitions in quantum-enhanced experiments
- URL: http://arxiv.org/abs/2310.03061v3
- Date: Thu, 6 Jun 2024 22:10:35 GMT
- Title: Entanglement transitions in quantum-enhanced experiments
- Authors: Shane P. Kelly, Jamir Marino,
- Abstract summary: A quantum-enhanced experiment, in which information is transduced from a system of interest and processed on a quantum computer, has the possibility of exponential advantage in sampling tasks.
We demonstrate that, similar to the measurement induced phase transition(MIPT) occurring in traditional experiments, quantum-enhanced experiments can also show entanglement phase transitions.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: A quantum-enhanced experiment, in which information is transduced from a system of interest and processed on a quantum computer, has the possibility of exponential advantage in sampling tasks over a traditional experiment, where only the measurement outcomes of projective or weak measurements are stored on a classical computer. In this work, we demonstrate that, similar to the measurement induced phase transition~(MIPT) occurring in traditional experiments, quantum-enhanced experiments can also show entanglement phase transitions. We introduce a noisy transduction operation which replaces projective measurements and acts independently on two qubits, recording the quantum state of one qubit in the measurement apparatus, while erasing the quantum state of the other qubit with the environment. We then construct a random brickwork circuit which shows an entanglement transition tuned by the rate of noisy transduction operations. Below the critical rate of noisy transduction, an extensive amount of entanglement is generated between regions of the system and apparatus, while above the critical rate, entanglement satisfies area law scaling. Our work delineates the prerequisites for quantum-enhanced experiments to manifest entanglement transitions, thereby establishing a foundational framework that connects quantum-enhanced sensing with emergent entanglement phenomena.
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