Quantum circuit complexity has played a central role in recent advances in holography and many-body physics. Within quantum field theory, it has typically been studied in a Lorentzian (real-time) framework. In a departure from standard treatments, we aim to quantify the complexity of the Euclidean path integral. In this setting, there is no clear separation between space and time, and the notion of unitary evolution on a fixed Hilbert space no longer applies. As a proof of concept, we argue that the pants decomposition provides a natural notion of circuit complexity within the category of 2-dimensional bordisms and use it to formulate the circuit complexity of states and operators in 2-dimensional topological quantum field theory. We commen...
It is shown that every algebraic quantum field theory has an underlying functorial field theory whic...
In this paper, we first construct thermofield double states for bosonic string theory in the light-c...
We propose that finite cutoff regions of holographic spacetimes represent quantum circuits that map ...
Quantum computing is captured in the formalism of the monoidal subcategory of $\textbf{Vect}_{\mathb...
We probe the contraction from $2d$ relativistic CFTs to theories with Bondi-Metzner-Sachs (BMS) symm...
Early efforts to understand complexity in field theory have primarily employed a geometric approach ...
As a new step towards defining complexity for quantum field theories, we map Nielsen operator comple...
Motivated by recent studies of holographic complexity, we examine the question of circuit complexity...
Quantum computers will work by evolving a high tensor power of a small (e.g. two) dimensional Hilber...
In this work, we find that the complexity of quantum many-body states, defined as a spread in the Kr...
The vast majority of quantum states and unitaries have circuit complexity exponential in the number ...
In this paper, we analyze the circuit complexity for preparing ground states of quantum many-body sy...
We calculate the operator complexity for the displacement, squeeze and rotation operators of a quant...
We address the difference between integrable and chaotic motion in quantum theory as manifested by t...
We study the temporal evolution of the circuit complexity after the local quench where two harmonic ...
It is shown that every algebraic quantum field theory has an underlying functorial field theory whic...
In this paper, we first construct thermofield double states for bosonic string theory in the light-c...
We propose that finite cutoff regions of holographic spacetimes represent quantum circuits that map ...
Quantum computing is captured in the formalism of the monoidal subcategory of $\textbf{Vect}_{\mathb...
We probe the contraction from $2d$ relativistic CFTs to theories with Bondi-Metzner-Sachs (BMS) symm...
Early efforts to understand complexity in field theory have primarily employed a geometric approach ...
As a new step towards defining complexity for quantum field theories, we map Nielsen operator comple...
Motivated by recent studies of holographic complexity, we examine the question of circuit complexity...
Quantum computers will work by evolving a high tensor power of a small (e.g. two) dimensional Hilber...
In this work, we find that the complexity of quantum many-body states, defined as a spread in the Kr...
The vast majority of quantum states and unitaries have circuit complexity exponential in the number ...
In this paper, we analyze the circuit complexity for preparing ground states of quantum many-body sy...
We calculate the operator complexity for the displacement, squeeze and rotation operators of a quant...
We address the difference between integrable and chaotic motion in quantum theory as manifested by t...
We study the temporal evolution of the circuit complexity after the local quench where two harmonic ...
It is shown that every algebraic quantum field theory has an underlying functorial field theory whic...
In this paper, we first construct thermofield double states for bosonic string theory in the light-c...
We propose that finite cutoff regions of holographic spacetimes represent quantum circuits that map ...