Gunhee Park 박건희
@quantumgunhee.bsky.social
PhD at Caltech
Tensor Networks, Open quantum systems, and Quantum Embedding theory
Garnet Chan group
Tensor Networks, Open quantum systems, and Quantum Embedding theory
Garnet Chan group
🧩 BP works well on tree-like lattices—but on 2D square lattices, loops introduce errors.
To go beyond this BP limit, we developed a cluster expansion for IF-BP that systematically captures loop-induced correlations.
To go beyond this BP limit, we developed a cluster expansion for IF-BP that systematically captures loop-induced correlations.
April 11, 2025 at 4:50 PM
🧩 BP works well on tree-like lattices—but on 2D square lattices, loops introduce errors.
To go beyond this BP limit, we developed a cluster expansion for IF-BP that systematically captures loop-induced correlations.
To go beyond this BP limit, we developed a cluster expansion for IF-BP that systematically captures loop-induced correlations.
🧠 A key idea: we shift the computational bottleneck from spatial to temporal entanglement.
While spatial entanglement grows linearly with time, we find that temporal entanglement entropy grows only logarithmically—enabling simulations with polynomial cost.
While spatial entanglement grows linearly with time, we find that temporal entanglement entropy grows only logarithmically—enabling simulations with polynomial cost.
April 11, 2025 at 4:50 PM
🧠 A key idea: we shift the computational bottleneck from spatial to temporal entanglement.
While spatial entanglement grows linearly with time, we find that temporal entanglement entropy grows only logarithmically—enabling simulations with polynomial cost.
While spatial entanglement grows linearly with time, we find that temporal entanglement entropy grows only logarithmically—enabling simulations with polynomial cost.
🔄 Instead of representing the wavefunction as a tensor network state,
we reformulate the dynamics as a path integral over the subsystem—captured by an influence functional MPS (IF-MPS).
We adapt BP to efficiently construct the IF-MPS for 2D lattices.
we reformulate the dynamics as a path integral over the subsystem—captured by an influence functional MPS (IF-MPS).
We adapt BP to efficiently construct the IF-MPS for 2D lattices.
April 11, 2025 at 4:50 PM
🔄 Instead of representing the wavefunction as a tensor network state,
we reformulate the dynamics as a path integral over the subsystem—captured by an influence functional MPS (IF-MPS).
We adapt BP to efficiently construct the IF-MPS for 2D lattices.
we reformulate the dynamics as a path integral over the subsystem—captured by an influence functional MPS (IF-MPS).
We adapt BP to efficiently construct the IF-MPS for 2D lattices.
🚀 New paper out on arXiv!
We developed a tensor network algorithm to simulate quantum dynamics in 2D lattices, combining the concept of tensor network influence functional (TN-IF) and belief propagation (BP).
arxiv.org/abs/2504.07344
We developed a tensor network algorithm to simulate quantum dynamics in 2D lattices, combining the concept of tensor network influence functional (TN-IF) and belief propagation (BP).
arxiv.org/abs/2504.07344
April 11, 2025 at 4:50 PM
🚀 New paper out on arXiv!
We developed a tensor network algorithm to simulate quantum dynamics in 2D lattices, combining the concept of tensor network influence functional (TN-IF) and belief propagation (BP).
arxiv.org/abs/2504.07344
We developed a tensor network algorithm to simulate quantum dynamics in 2D lattices, combining the concept of tensor network influence functional (TN-IF) and belief propagation (BP).
arxiv.org/abs/2504.07344
I am volunteering at the DCP table at APS 2025.
The table is in front of the room 204B Annaheim convention center.
Say hi to me if you are nearby!
The table is in front of the room 204B Annaheim convention center.
Say hi to me if you are nearby!
March 18, 2025 at 4:03 PM
I am volunteering at the DCP table at APS 2025.
The table is in front of the room 204B Annaheim convention center.
Say hi to me if you are nearby!
The table is in front of the room 204B Annaheim convention center.
Say hi to me if you are nearby!