Bulletin of the American Physical Society
APS March Meeting 2023
Volume 68, Number 3
Las Vegas, Nevada (March 5-10)
Virtual (March 20-22); Time Zone: Pacific Time
Session T1: Quantum Information and Spacetime |
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Chair: Brian Swingle, Brandeis University Room: Room 128 |
Sunday, March 5, 2023 8:30AM - 9:30AM |
T1.00001: Quantum Information and Spacetime Gregory Bentsen Quantum gravity is concerned with the search for consistent models of quantum spacetime and the experimental challenge of determining which model describes nature. Experimental access to the quantum physics of spacetime is still challenging, but we are currently seeing dramatic advances in our theoretical understanding of quantum gravity. These developments are occurring primarily in the context of so-called holographic models like the AdS/CFT correspondence, with ideas from quantum information science and many-body physics, including information scrambling, tensor networks, and quantum error correction codes, playing a central role. Moreover, there is the exciting possibility that such models of quantum gravity can be experimentally studied in the near future using quantum simulators. This tutorial will introduce some of the organizing ideas and open questions in the field of quantum gravity and describe how ideas ranging from computational complexity to quantum codes are being used to understand how spacetime can emerge from microphysics. |
Sunday, March 5, 2023 9:30AM - 10:30AM |
T1.00002: Quantum Information and Spacetime ChunJun (Charles) Cao Quantum gravity is concerned with the search for consistent models of quantum spacetime and the experimental challenge of determining which model describes nature. Experimental access to the quantum physics of spacetime is still challenging, but we are currently seeing dramatic advances in our theoretical understanding of quantum gravity. These developments are occurring primarily in the context of so-called holographic models like the AdS/CFT correspondence, with ideas from quantum information science and many-body physics, including information scrambling, tensor networks, and quantum error correction codes, playing a central role. Moreover, there is the exciting possibility that such models of quantum gravity can be experimentally studied in the near future using quantum simulators. This tutorial will introduce some of the organizing ideas and open questions in the field of quantum gravity and describe how ideas ranging from computational complexity to quantum codes are being used to understand how spacetime can emerge from microphysics. |
Sunday, March 5, 2023 10:30AM - 11:30AM |
T1.00003: Quantum Information and Spacetime Alex May Quantum gravity is concerned with the search for consistent models of quantum spacetime and the experimental challenge of determining which model describes nature. Experimental access to the quantum physics of spacetime is still challenging, but we are currently seeing dramatic advances in our theoretical understanding of quantum gravity. These developments are occurring primarily in the context of so-called holographic models like the AdS/CFT correspondence, with ideas from quantum information science and many-body physics, including information scrambling, tensor networks, and quantum error correction codes, playing a central role. Moreover, there is the exciting possibility that such models of quantum gravity can be experimentally studied in the near future using quantum simulators. This tutorial will introduce some of the organizing ideas and open questions in the field of quantum gravity and describe how ideas ranging from computational complexity to quantum codes are being used to understand how spacetime can emerge from microphysics. |
Sunday, March 5, 2023 11:30AM - 12:30PM |
T1.00004: Quantum Information and Spacetime Isaac H Kim Quantum gravity is concerned with the search for consistent models of quantum spacetime and the experimental challenge of determining which model describes nature. Experimental access to the quantum physics of spacetime is still challenging, but we are currently seeing dramatic advances in our theoretical understanding of quantum gravity. These developments are occurring primarily in the context of so-called holographic models like the AdS/CFT correspondence, with ideas from quantum information science and many-body physics, including information scrambling, tensor networks, and quantum error correction codes, playing a central role. Moreover, there is the exciting possibility that such models of quantum gravity can be experimentally studied in the near future using quantum simulators. This tutorial will introduce some of the organizing ideas and open questions in the field of quantum gravity and describe how ideas ranging from computational complexity to quantum codes are being used to understand how spacetime can emerge from microphysics. |
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