Dilute neutron star matter from neural-network quantum states

Low-density neutron matter is characterized by fascinating emergent quantum phenomena, such as the formation of Cooper pairs and the onset of superfluidity. We model this density regime by capitalizing on the expressivity of the hidden-nucleon neural-network quantum states combined with variational Monte Carlo and stochastic reconfiguration techniques. Our approach is competitive with the auxiliary-field diffusion Monte Carlo method at a fraction of the computational cost. Using a leading-order pionless effective field theory Hamiltonian, we compute the energy per particle of infinite neutron matter and compare it with those obtained from highly realistic interactions. In addition, a comparison between the spin-singlet and triplet two-body distribution functions indicates the emergence of pairing in the 1S0 channel.

Dilute neutron star matter from neural-network quantum states

Brain microstructural and functional MRI: developments and application to a rat model of Alzheimer's disease

Gamma-Blind Fast Neutron Detection for Spent Nuclear Fuel Characterization

HighNESS conceptual design report: Volume II. The NNBAR experiment.

Gamma-Blind Fast Neutron Detection for Spent Nuclear Fuel Characterization

HighNESS conceptual design report: Volume II. The NNBAR experiment.

Brain microstructural and functional MRI: developments and application to a rat model of Alzheimer's disease