1. Accurate Gauge-Invariant Tensor Network Simulations for Abelian Lattice Gauge Theory in (2+1)D: Ground State and Real-time Dynamics.
   Yantao Wu, Wen-Yuan Liu.
   Phys. Rev. Lett. 135, 130401, 2025. arXiv:2503.20566
2. Alternating and Gaussian fermionic Isometric Tensor Network States.
   Yantao Wu, Zhehao Dai, Sajant Anand, Sheng-Hsuan Lin, Qi Yang, Lei Wang, Frank Pollmann, Michael Zaletel.
   PRX Quantum 6, 040324, 2025. arXiv:2502.10695
3. Solving the Hubbard model with Neural Quantum States.
   Yuntian Gu, Wenrui Li, Heng Lin, Bo Zhan, Ruichen Li, Yifei Huang, Di He, Yantao Wu, Tao Xiang, Mingpu Qin, Liwei Wang, Dingshun Lv.
   arxiv:2507.02644
4. Algorithms for variational Monte Carlo calculations of fermion PEPS in the swap gates formulation and the detailed balance of tensor network sequential sampling.
   Yantao Wu, Zhehao Dai.
   arXiv:2506.20106
5. No-go theorems for sequential preparation of two-dimensional chiral states via channel-state correspondence
   Ruihua Fan, Yantao Wu, Yimu Bao, Zhehao Dai.
   arxiv:2511.19612

----------------------------------------------------Before IOP----------------------------------------------------

1. Fermionic Isometric Tensor Network States in Two Dimensions.
   Zhehao Dai*, Yantao Wu*, Taige Wang, Michael Zaletel.
   Phys. Rev. Lett. 134, 026502, 2025. arXiv:2211.00043
2. Improving Schrodinger Equation Implementations with Gray Code for Adiabatic Quantum Computers.
   Chia Cheng Chang, Kenneth McElvain, Ermal Rrapaj, Yantao Wu.
   PRX Quantum 3, 020356, 2022. arXiv:2103.08056
3. Monte Carlo Renormalization Group for Classical Lattice Models with Quenched Disorder.
   Yantao Wu, Roberto Car.
   Phys. Rev. Lett. 125, 190601, 2020. arXiv:1810.09579
4. Variational Approach to Monte Carlo Renormalization Group.
   Yantao Wu, Roberto Car. 
   Phys. Rev. Lett. 119, 220602, 2017. arXiv:1707.08683
5. Evidence for the Utility of Quantum Computing before Fault Tolerance.
   Youngseok Kim, Andrew Eddins, Sajant Anand, Ken Xuan Wei, Ewout Van Den Berg, Sami Rosenblatt, Hasan Nayfeh, Yantao Wu, Michael Zaletel, Kristan Temme, Abhinav Kandala.
   Nature 618 (7965), 500-505, 2023. 
6. Tensor network Python (TeNPy) version 1.
   J Hauschild, J Unfried, S Anand, B Andrews, M Bintz, U Borla, S Divic, M Drescher, J Geiger, M Hefel, K Hémery, W Kadow, J Kemp, N Kirchner, VS Liu, G Möller, D Parker, M Rader, A Romen, S Scalet, L Schoonderwoerd, M Schulz, T Soejima, P Thoma, Y Wu, P Zechmann, L Zweng, RSK Mong, MP Zaletel, F Pollmann.
   SciPost Phys Code.41, 2024.
7. Two-dimensional Isometric Tensor Network States on an Infinite Strip.
   Yantao Wu, Sajant Anand, Sheng-Hsuan Lin, Frank Pollmann, Michael Zaletel.
   Phys. Rev. B 107, 245118, 2023. arXiv:2211.14337
8. Time-dependent Variational Principle for Mixed Matrix Product States in the Thermodynamic Limit.
   Yantao Wu.
   Phys. Rev. B 102, 134306, 2020. arXiv:2007.15035
9. Continuous-time Monte Carlo Renormalization Group.
   Yantao Wu, Roberto Car.
   Phys. Rev. B 102, 014456, 2020. arXiv:2004.08765
10. Dynamical Quantum Phase Transitions of Quantum Spin Chains with an Loschmidt-rate Critical Exponent Equal to 1/2.
    Yantao Wu.
    Phys. Rev. B 101, 064427, 2020. arXiv:1912.04181
11. Nonequilibrium Renormalization Group Fixed Points of the Quantum Clock Chain and the Quantum Potts Chain.
    Yantao Wu.
    Phys. Rev. B 101, 014305, 2020. arXiv:1906.07945
12. Quantum Momentum Distribution and Quantum Entanglement in the Deep Tunneling Regime. 
    Yantao Wu, Roberto Car.
    J. Chem. Phys. 152, 024106, 2020. arXiv:1912.05072
13. Determinantion of the Critical Manifold Tangent Space and Curvature with Monte Carlo Renormalization Group.
    Yantao Wu, Roberto Car.
    Phys. Rev. E 100, 022138, 2019. arXiv:1903.08231
14. Tangent Space to the Manifold of Critical Classical Hamiltonians Representable by Tensor Networks.
    Yantao Wu.
    Phys. Rev. E 100, 023306, 2019. arXiv:1903.12137