Beni Yoshida | Perimeter Institute

Teaching Affiliations

Perimeter Institute is committed to diversity within its community and I welcome applications from underrepresented groups.

Research Interests

Quantum Information Theory, Quantum Gravity, Condensed Matter Theory. I focus on applications of quantum information theory to problems of quantum many-body physics and quantum gravity. In particular, I have used the techniques of quantum coding theory to construct toy models of the AdS/CFT correspondence and discovered information retrieval processes from black holes by using the quantum information scrambling phenomena.

Positions Held

5 Year Senior Postdoctoral Researcher, Perimeter Institute for Theoretical Physics, 2015-2017
Burke Fellow, Institute for Theoretical Physics , Caltech, 2012-2015

Awards

Nishinomiya Yukawa Memorial Prize in Theoretical Physics, Nishinomiya Yukawa Prize, 2021

Recent Publications

Mori, T., & Yoshida, B. (2026). Does connected wedge imply distillable entanglement?. Journal of High Energy Physics, 2026(1), 125. doi:10.1007/jhep01(2026)125
Mori, T., & Yoshida, B. (2025). Baby universe as logical qubits: information recovery in random encoding. doi:10.48550/arxiv.2511.20747
Khanian, Z., Lee, D., Leung, D., Li, Z., May, A., Mori, T., . . . Yoshida, B. (2025). Entanglement sharing schemes. doi:10.48550/arxiv.2509.21462
Lee, D., & Yoshida, B. (2025). Chiral Color Code : Single-shot error correction for exotic topological order. doi:10.48550/arxiv.2509.18324
Mori, T., & Yoshida, B. (2025). Does connected wedge imply distillable entanglement?. doi:10.48550/arxiv.2411.03426
Tan, Y., Roberts, B., Tantivasadakarn, N., Yoshida, B., & Yao, N. Y. (2025). Fracton models from product codes. Physical Review Research, 7(3), l032062. doi:10.1103/f48m-rlh3
Bravyi, S., Lee, D., Li, Z., & Yoshida, B. (2025). How Much Entanglement Is Needed for Quantum Error Correction?. Physical Review Letters, 134(21), 210602. doi:10.1103/physrevlett.134.210602
Li, Z., Lee, D., & Yoshida, B. (2025). How Much Entanglement Is Needed for Topological Codes and Mixed States with Anomalous Symmetry?. Physical Review X, 15(2), 021090. doi:10.1103/pw12-kdjx
Li, Z., Mori, T., & Yoshida, B. (2025). Tripartite Haar random state has no bipartite entanglement. doi:10.48550/arxiv.2502.04437
Li, Z., Lee, D., & Yoshida, B. (2024). How Much Entanglement Is Needed for Topological Codes and Mixed States with Anomalous Symmetry?. doi:10.48550/arxiv.2405.07970
Lee, D., & Yoshida, B. (2024). Randomly Monitored Quantum Codes. doi:10.48550/arxiv.2402.00145
Sang, S., Li, Z., Hsieh, T. H., & Yoshida, B. (2023). Ultrafast Entanglement Dynamics in Monitored Quantum Circuits. PRX Quantum, 4(4), 040332. doi:10.1103/prxquantum.4.040332
Mori, T., & Yoshida, B. (2023). Exploring causality in braneworld/cutoff holography via holographic scattering. Journal of High Energy Physics, 2023(10), 104. doi:10.1007/jhep10(2023)104

Seminars

Quantum Information Theoretic Proof of Chirality, Quantum Information, 2025/10/15, PIRSA:25100146
Simple lattice model for single-shot error-correction in three-dimensional topological phases, March Meeting, 2025/03/21
Long-range entangled mixed state phase, University of Chicago, 2024/11/12
Entanglement Distillation in Holography, Waterloo-Munich Joint Workshop, 2024/10/03, PIRSA:24100056
Does connected wedge imply entanglement?, 2024/07/25
Holographic scattering and quantum error-correction, 2024/03/24
Quantum Error-Correction and Holographic Task, QPV 2023: Advances in quantum position verification, 2023/09/19, PIRSA:23090016
Causality at the End-of-World, Quantum Spacetime in the Cosmos: From Conception to Reality, 2023/05/10, PIRSA:23050121
Quantum error-correction and quantum gravity, Colloquium, 2023/04/05, PIRSA:23040082