Magnetic refrigeration techniques based on the magnetocaloric effect (MCE) have recently been demonstrated as a promising alternative to conventional vapour-cycle refrigeration. In a material displaying the MCE, the alignment of randomly oriented magnetic moments by an external magnetic field results in heating. This heat can then be removed from the MCE material to the ambient atmosphere by heat transfer. If the magnetic field is subsequently turned off, the magnetic moments randomize again, which leads to cooling of the material below the ambient temperature. Here we report the discovery of a large magnetic entropy change in MnFeP0.45As0.55, a material that has a Curie temperature of about 300 K and which allows magnetic refrigeration at room temperature. The magnetic entropy changes reach values of 14.5 J K-1 kg-1 and 18 J K-1 kg-1 for field changes of 2 T and 5 T, respectively. The so-called giant-MCE material Gd5Ge2Si2 (ref. 2) displays similar entropy changes, but can only be used below room temperature. The refrigerant capacity of our material is also significantly greater than that of Gd (ref. 3). The large entropy change is attributed to a field-induced first-order phase transition enhancing the effect of the applied magnetic field.
The efficient coupling between lattice degrees of freedom and spin degrees of
freedom in magnetic materials can be used for refrigeration and energy
conversion. This coupling is enhanced in materials exhibiting the giant
magnetocaloric effect. First principle electronic structure calculations on
hexagonal MnFe(P, Si) reveal a new form of magnetism: the coexistence of strong
and weak magnetism in alternate atomic layers. The weak magnetism of Fe layers
(disappearance of local magnetic moments at the Curie temperature) is
responsible for a strong coupling with the crystal lattice while the strong
magnetism in adjacent Mn-layers ensures Curie temperatures high enough to
enable operation at and above room temperature. Varying the composition on
these magnetic sublattices gives a handle to tune the working temperature and
to achieve a strong reduction of the undesired thermal hysteresis. In this way
we design novel materials based on abundantly available elements with
properties matched to the requirements of an efficient refrigeration or
energy-conversion cycle.Comment: 6 pages, 6 figure
The MnCoGe alloy can crystallize in either the hexagonal Ni2In- or the orthorhombic TiNiSi-type of structure. In both phases MnCoGe behaves like a typical ferromagnet with a second-order magnetic phase transition. For MnCoGeBx with B on interstitial positions, we discover a giant magnetocaloric effect associated with a single first-order magnetostructural phase transition, which can be achieved by tuning the magnetic and structural transitions to coincide. The results obtained on the MnCoGe-type alloys may be extensible to other types of magnetic materials undergoing a first-order structural transformation and can open up some possibilities for searching magnetic refrigerants for room-temperature applications.
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