Caloric effect–based cooling technologies are promising for high-efficiency cooling with safe, low–global warming potential refrigerants is a grand challenge for tackling climate change. The recently developed ionocaloric effect and the accompanying thermodynamic cycle showed a high coefficient of performance of 30% relative to Carnot as well as a higher adiabatic temperature change and entropy change per unit mass and volume compared with other caloric effects under low applied field strengths. However, the previous work only demonstrated the viability of such an ionocaloric Stirling refrigeration cycle in separate steps ex-situ for a single type of binary solution system without testing the full cycle. It is thus important to realize and evaluate actual device of such cycles for cooling applications and explore other potential materials and device configurations for higher power output and COP.