Tailoring the hyperthermia potential of magnetite nanoparticles via gadolinium ION substitution

“…Later, rare earth oxides (REO) materials have gone mainstream in magnetic, catalytic, optical, sensor, and cryogenic applications over the last few decades. [14][15][16][17][18][19][20][21][22] REO's are of high technical importance in the refrigeration domain because of their ability to experience isothermal entropy change when external stimuli such as an electric force, magnetic field, stress, or pressure are applied. [23][24][25] By switching one control parameter to another, several driving fields may produce greater thermal changes with a smaller magnetic field across a broad range of operating temperatures and remove hysteresis.…”

Enhanced Cryogenic Magnetocaloric Performance in Te Doped Dy₂O₃

“…Later, rare earth oxides (REO) materials have gone mainstream in magnetic, catalytic, optical, sensor, and cryogenic applications over the last few decades. [14][15][16][17][18][19][20][21][22] REO's are of high technical importance in the refrigeration domain because of their ability to experience isothermal entropy change when external stimuli such as an electric force, magnetic field, stress, or pressure are applied. [23][24][25] By switching one control parameter to another, several driving fields may produce greater thermal changes with a smaller magnetic field across a broad range of operating temperatures and remove hysteresis.…”

Enhanced Cryogenic Magnetocaloric Performance in Te Doped Dy₂O₃

Magnetite/Rhodamine 6G nanoparticles internalization in Neurospora crassa cells: towards the magnetic hyperthermia application

Hierarchical iron oxide nanocomposite: Bundle-like morphology, magnetic properties and potential biomedical application