Add to ORKGTensor-network states (TNS) are a promising but numerically challenging tool for simulating two-dimensional (2D) quantum many-body problems. We introduce an isometric restriction of the TNS ansatz that allows for highly efficient contraction of the network. We consider two concrete applications using this ansatz. First, we show that a matrix-product state representation of a 2D quantum state can be iteratively transformed into an isometric 2D TNS. Second, we introduce a 2D version of the time-evolving block decimation algorithm for approximating of the ground state of a Hamiltonian as an isometric TNS-which we demonstrate for the 2D transverse field Ising model
We propose a procedure to transform two-dimensional (2D) tensor network states into one-dimensional ...
Tensor network states provide an efficient class of states that faithfully capture strongly correlat...
We propose an efficient algorithm for simulating quantum many-body systems in two spatial dimensions...
Tensor-network states (TNS) are a promising but numerically challenging tool for simulating two-dime...
The exact contraction of a generic two-dimensional (2D) tensor network state (TNS) is known to be ex...
We investigate the computational power of the recently introduced class of isometric tensor network ...
We generalize isometric tensor network states to fermionic systems, paving the way for efficient ada...
By taking inspiration from the backflow transformation for correlated systems, we introduce a novel ...
Theory of quantum many-body systems plays a key role in understanding the properties of phases of ma...
We present a novel mapping for studying 2D many-body quantum systems by solving an effective, one-di...
We introduce a novel tensor network structure augmenting the well-established tree tensor network re...
We propose an efficient algorithm for simulating quantum many-body systems in two spatial dimensions...
Tensor network states provide an efficient class of states that faithfully capture strongly correlat...
We propose an efficient algorithm for simulating quantum many-body systems in two spatial dimensions...
It appears that the tensor network ansatz, while not quite complete, is an efficient coordinate syst...
We propose a procedure to transform two-dimensional (2D) tensor network states into one-dimensional ...
Tensor network states provide an efficient class of states that faithfully capture strongly correlat...
We propose an efficient algorithm for simulating quantum many-body systems in two spatial dimensions...
Tensor-network states (TNS) are a promising but numerically challenging tool for simulating two-dime...
The exact contraction of a generic two-dimensional (2D) tensor network state (TNS) is known to be ex...
We investigate the computational power of the recently introduced class of isometric tensor network ...
We generalize isometric tensor network states to fermionic systems, paving the way for efficient ada...
By taking inspiration from the backflow transformation for correlated systems, we introduce a novel ...
Theory of quantum many-body systems plays a key role in understanding the properties of phases of ma...
We present a novel mapping for studying 2D many-body quantum systems by solving an effective, one-di...
We introduce a novel tensor network structure augmenting the well-established tree tensor network re...
We propose an efficient algorithm for simulating quantum many-body systems in two spatial dimensions...
Tensor network states provide an efficient class of states that faithfully capture strongly correlat...
We propose an efficient algorithm for simulating quantum many-body systems in two spatial dimensions...
It appears that the tensor network ansatz, while not quite complete, is an efficient coordinate syst...
We propose a procedure to transform two-dimensional (2D) tensor network states into one-dimensional ...
Tensor network states provide an efficient class of states that faithfully capture strongly correlat...
We propose an efficient algorithm for simulating quantum many-body systems in two spatial dimensions...