2026
M. Kim and C. Oh*, “On the Fundamental Resource for Exponential Advantage in Quantum Channel Learning,” arXiv:2507.11089 (2025). (accepted at Nature Communications)
R. Nehra*, C. Oh*, L. Jiang, and A. Marandi, “All-optical Loss-tolerant Distributed Quantum Sensing,” arXiv:2407.13654v1 (2024). (accepted at npj Quantum Inf.)
Y. Wang, C. Oh, J. Liu, L. Jiang, and S. Zhou, “Advancing quantum imaging through learning theory,” Nat Commun (2025).
J. Heo, S. Park and C. Oh*, "Classical simulation of a quantum circuit with noisy magic inputs," arXiv:2601.10111 (2026).
S. Jeon and C. Oh*, “On the query complexity of unitary channel certification,” npj Quantum Inf 12, 2 (2026).
2025
B. Go and C. Oh, H.jeong, "Sufficient conditions for hardness of lossy Gaussian boson sampling," arXiv:2511.07853 (2025).
S. Park and C. Oh*, "Matrix product state approach to lossy boson sampling and noisy IQP sampling," arXiv:2510.24137 (2025).
S.-u. Lee, S. Ghosh, C. Oh, K. Noh, B. Fefferman, L. Jiang, "Classical simulation of noisy random circuits from exponential decay of correlation," arXiv:2510.06328 (2025).
J. T. Iosue, Y.-X. Wang, I. Datta, S. Ghosh, C. Oh, B. Fefferman, and A. V. Gorshkov, “Higher moment theory and learnability of bosonic states,” arXiv:2510.01610 (2025).
Z.-H. Liu, R. Brunel, E. E. B. Østergaard, O. Cordero, S. Chen, Y. Wong, J. A. H. Nielsen, A. B. Bregnsbo, S. Zhou, H.-Y. Huang, C. Oh, L. Jiang, J. Preskill, J. S. Neergaard-Nielsen, and U. L. Andersen, “Quantum learning advantage on a scalable photonic platform,” Science 389, 1332 (2025).
B. Go, C. Oh*, and H. Jeong*, “Quantum computational advantage of noisy boson sampling with partially distinguishable photons,” PRX Quantum 6, 030362 (2025).
C. Oh* and Y. Lim, “Classical algorithms for measurement-adaptive Gaussian circuits,” arXiv:2509.00746 (2025).
C. Oh, “Classical simulability of constant-depth linear-optical circuits with noise,” npj Quantum Inf. 11, 126 (2025).
H. Kwon, C. Oh, Y. Lim, H. Jeong, S.-W. Lee, and L. Jiang, “Virtual purification complements quantum error correction in quantum metrology,” arXiv:2503.12614 (2025).
Y. Lim and C. Oh*, “Efficient classical algorithms for linear optical circuits,” arXiv:2502.12882 (2025).
C. Oh*, “Recent Theoretical and Experimental Progress on Boson Sampling,” Curr. Opt. Photon., 9, 1 (2025).
E. Coroi and C. Oh*, “Exponential advantage in continuous-variable quantum state learning,” arXiv:2501.17633 (2025).
2024
C. Oh*, S. Chen*, Y. Wong, S. Zhou, H.-Y. Huang, J. A. H. Nielsen, Z.-H. Liu, J. S. Neergaard-Nielsen, U. L. Andersen, L. Jiang, J. Preskill, “Entanglement-enabled advantage for learning a bosonic random displacement channel,” Phys. Rev. Lett. 133, 230604 (2024).
S.-u. Lee, C. Oh, Y. Wong, S. Chen, L. Jiang, “Universal Spreading of Conditional Mutual Information in Noisy Random Circuits,” Phys. Rev. Lett. 133, 200402 (2024).
Y.-X. Wang, J. Bringewatt, A. Seif, A. J. Brady, C. Oh, and A. V. Gorshkov, “Exponential entanglement advantage in sensing correlated noise,” arXiv:2410.05878 (2024).
C. Oh*, M. Liu*, Y. Alexeev, B. Fefferman, and L. Jiang, “Classical algorithm for simulating experimental Gaussian boson sampling,” Nat. Phys. 20, 1461 (2024).
C. Oh, B. Fefferman, L. Jiang, and N. Quesada, “Quantum-inspired classical algorithm for graph problems by Gaussian boson sampling,” PRX Quantum 5, 020341 (2024).
B. Go, C. Oh*, L. Jiang, and H. Jeong, “Exploring Shallow-Depth Boson Sampling: Towards Scalable Quantum Supremacy,” Phys. Rev. A 109, 052613 (2024) (Editors’ Suggestion).
B. Go, C. Oh*, and H. Jeong*, “On computational complexity and average-case hardness of shallow-depth boson sampling,” arXiv:2405.01786 (2024).
S. Chen, C. Oh, S. Zhou, H.-Y. Huang, and L. Jiang, “Tight bounds on Pauli channel learning without entanglement,” Phys. Rev. Lett. 132, 180805 (2024).
H. Kwon, C. Oh*, Y. Lim, H. Jeong, and L. Jiang, “Efficacy of virtual purification-based error mitigation on quantum metrology,” Phys. Rev. A 109, 022410 (2024).
C. Oh, Y. Lim, Y. Wong, B. Fefferman, and L. Jiang, “Quantum-inspired classical algorithm for molecular vibronic spectra,” Nat. Phys. 20, 225 (2024).