Monte Carlo String/M-theory Collaboration

We study the two matrix models using deep learning methods and quantum simulations. We benchmark the results against lattice Monte Carlo simulations.

Neural networks enable an important calculation in a popular approach to unifying quantum mechanics with general relativity

We study the thermodynamics of the ‘ungauged’ D0-brane matrix model by Monte Carlo simulation. Our results appear to be consistent with the conjecture by Maldacena and Milekhin.

A black hole described in SU(N) gauge theory consists of N D-branes. As a proof of the concept, we perform an explicit calculation in the matrix model dual to the black zero-brane in type IIA string theory. We study the geometry of the black hole in this dual representation using lattice Monte Carlo simulations.

Matrix quantum mechanics plays various important roles in theoretical physics, such as a holographic description of quantum black …

Matrix quantum mechanics plays various important roles in theoretical physics, such as a holographic description of quantum black …

Matrix quantum mechanics plays various important roles in theoretical physics, such as a holographic description of quantum black …

Matrix quantum mechanics plays various important roles in theoretical physics, such as a holographic description of quantum black …

Quantum mechanics is at the core of our understanding of the subatomic world. Moreover, it is driving a new industry based on quantum …

Can we use quantum computing to answer important questions in quantum field theory? Once we can formulate the problem on a quantum …

Matrix quantum mechanics plays various important roles in theoretical physics, such as a holographic description of quantum black …

Lattice field theories are a useful tool to define gauge theories in their non- perturbative regime. At the same time, the …