It is for the first time that quantum simulation for high-energy physics (HEP) is studied in the
US decadal particle-physics community planning, and in fact until recently, this was not …

Key static and dynamic properties of matter—from creation in the Big Bang to evolution into
subatomic and astrophysical environments—arise from the underlying fundamental …

Over recent years, the relatively young field of quantum simulation of lattice gauge theories,
aiming at implementing simulators of gauge theories with quantum platforms, has gone …

Quantum computers offer the possibility to implement lattice gauge theory in Minkowski
rather than Euclidean spacetime, thus allowing calculations of processes that evolve in real …

Hamiltonian formulation of lattice gauge theories (LGTs) is the most natural framework for
the purpose of quantum simulation, an area of research that is growing with advances in …

Quantum field theories are the cornerstones of modern physics, providing relativistic and
quantum mechanical descriptions of physical systems at the most fundamental level …

Lattice gauge theory is an essential tool for strongly interacting non-Abelian fields, such as
those in quantum chromodynamics where lattice results have been of central importance for …

Lattice gauge theory should be able to address significant new scientific questions when
implemented on quantum computers. In practice, error-mitigation techniques have already …

Quantum chromodynamics (QCD)—the theory of quarks and gluons—has been studied for
decades, but it is yet to be fully understood. A recent example is the prediction and …

The successes and limitations of statistical sampling for a sequence of models studied in the
context of lattice QCD are discussed and the need for new methods to deal with finite …