Journal
CRYSTALS
Volume 13, Issue 3, Pages -Publisher
MDPI
DOI: 10.3390/cryst13030397
Keywords
crystal growth; floating-zone technique; garnets; frustrated magnet
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Mn3Al2Ge3O12 is a garnet compound with high degree of geometrical frustration. It exhibits intriguing magnetic properties, including long range hidden order derived from multipoles formed from 10-spin loops. The crystal structure of Mn3Al2Ge3O12 is similar to the well-studied Gd garnets, and its magnetic properties are closest to those of gadolinium garnets. A large, high quality single crystal of Mn3Al2Ge3O12 was successfully grown by the floating zone method, allowing for detailed investigations of its magnetic properties.
Mn3Al2Ge3O12 is a member of the garnet family of compounds, A(3)B(2)(CO4)(3), whose magnetic properties are affected by a high degree of geometrical frustration. The magnetic frustration is at the origin of the intriguing magnetic properties that these materials exhibit, such as a long range hidden order derived from multipoles formed from 10-spin loops in the gadolinium gallium garnet, Gd3Ga5O12. Mn3Al2Ge3O12 garnet is isostructural to the thoroughly investigated Gd garnets, Gd3Ga5O12 and Gd3Al5O12. Moreover, in Mn3Al2Ge3O12, the Heisenberg-like Mn2+ magnetic ions (L= 0) are also arranged in corner sharing triangles that form a hyperkagome structure. The identical crystallographic structures and similar Heisenberg-like behaviour of the magnetic ions make manganese aluminium germanium garnet the closest compound to the gadolinium garnets in its magnetic properties. Here, we report, for the first time, the growth of a large, high quality single crystal of the Mn3Al2Ge3O12 garnet by the floating zone method. X-ray diffraction techniques were used to characterise and confirm the high crystalline quality of the Mn3Al2Ge3O12 crystal boule. Temperature-dependent magnetic susceptibility measurements reveal an antiferromagnetic ordering of the Mn2+ ions below T-N= 6.5 K. The high quality of the single crystal obtained makes it ideal for detailed investigations of the magnetic properties of the system, especially using neutron scattering techniques.
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