Article Synopsis
- Quantum computers, specifically superconducting quantum annealers, can quickly generate solutions to complex problems beyond the capabilities of conventional computers.
- Researchers demonstrated that these quantum processors can efficiently model dynamics in spin glasses using principles of the Schrödinger equation.
- Compared to traditional methods like tensor networks and neural networks, quantum annealers provide greater accuracy in a shorter timeframe for solving practical problems.
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Article Abstract
Quantum computers hold the promise of solving certain problems that lie beyond the reach of conventional computers. However, establishing this capability, especially for impactful and meaningful problems, remains a central challenge. Here, we show that superconducting quantum annealing processors can rapidly generate samples in close agreement with solutions of the Schrödinger equation. We demonstrate area-law scaling of entanglement in the model quench dynamics of two-, three-, and infinite-dimensional spin glasses, supporting the observed stretched-exponential scaling of effort for matrix-product-state approaches. We show that several leading approximate methods based on tensor networks and neural networks cannot achieve the same accuracy as the quantum annealer within a reasonable time frame. Thus, quantum annealers can answer questions of practical importance that may remain out of reach for classical computation.
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| http://dx.doi.org/10.1126/science.ado6285 | DOI Listing |