Magnetic Refrigeration (MR) relies on the ability of a magnetic substance to undergo a significant change in entropy due to the application or removal of an applied field. In Active Magnetic Regenerators (AMR) the working material tends to operate near the magnetic ordering temperature, and, because the AMR creates a temperature gradient through the bed, the local magnetic permeability can vary widely. Due to geometry and non-uniform properties, an AMR bed is subject to non-negligible demagnetizing effects which can reduce the entropy change due to an applied field.

In this thesis, a numerical model is used to examine the effects of demagnetizing fields in an AMR. Model results for single-material (Gadolinium) beds show the impacts of temperature on effective magnetization and suggest that demagnetization effects will reduce the magnetic work performed at each location in the AMR. A solution to this problem is proposed