NMR serves as an important technique for probing rock pore space, such as pore structure
characterization, fluid identification, and petrophysical property testing, due to the reusability …

Nuclear magnetic resonance (NMR) provides a powerful toolbox for petrophysical
characterization of reservoir core plugs and fluids in the laboratory. Previously, there has …

Compressed sensing magnetic resonance methods have been used to image the time-
averaged velocity and turbulent kinetic energy in 3D for turbulent gas flowing through a bed …

Magnetic resonance (MR) velocity imaging has been used to investigate the gas flow in a
diesel particulate filter (DPF), with sulphur hexafluoride (SF 6) being used as the MR-active …

Abstract Three-dimensional (3D) imaging of the fluid distributions within the rock is essential
to enable the unambiguous interpretation of core flooding data. Magnetic resonance …

Predicted gas flow fields in wall-flow particulate filters, used for vehicular emissions
abatement, from both one-and three-dimensional numerical models have been validated for …

Accurate monitoring of multiphase displacement processes is essential for the development,
validation and benchmarking of numerical models used for reservoir simulation and for …

Magnetic resonance (MR) velocity imaging has been used to investigate the hydrodynamics
of turbulent gas flow through narrow packed beds (tube to pellet diameter ratio of N≈ 5) for …

The hydrodynamics in packed reactors strongly influences reactor performance. However,
limited experimental techniques are capable of non-invasively measuring the velocity field in …

Gas-phase compressed sensing magnetic resonance methods have been used to image
gas flow velocity and turbulent diffusivity in wall-flow particulate filters. Two-dimensional …