Add to ORKGUsing combined theoretical and experimental approaches, we studied the structural and electronic origin of the magnetic structure in hexagonal LuFeO3. Besides showing the strong exchange coupling that is consistent with the high magnetic ordering temperature, the previously observed spin reorientation transition is explained by the theoretically calculated magnetic phase diagram. The structural origin of this spin reorientation that is responsible for the appearance of spontaneous magnetization, is identified by theory and verified by x-ray diffraction and absorption experiments
Hexagonal manganites of the type \textit{R}MnO3 are well known examples of single-phase multiferroic...
To tune the magnetic properties of hexagonal ferrites, a family of magnetoelectric multiferroic mate...
Interface materials offer a means to achieve electrical control of ferrimagnetism at room temperatur...
Using combined theoretical and experimental approaches, we studied the structural and electronic ori...
The hexagonal phase of LuFeO3 is a rare example of a multiferroic material possessing a weak ferroma...
We report on the magnetic structure and ordering of hexagonal LuFeO3 films of variable thickness gro...
The structural, electric, and magnetic properties of bulk hexagonal LuFeO3 are investigated. Single ...
The crystal and magnetic structures of single-crystalline hexagonal LuFeO3 films have been studied u...
The crystal and magnetic structures of single-crystalline hexagonal LuFeO3 films have been studied u...
To tune the magnetic properties of hexagonal ferrites, a family of magnetoelectric multiferroic mate...
Strong spin-lattice coupling and prominent frustration effects observed in the 50 Fe-doped frustrate...
The structural transition at about 1000°C, from the hexagonal to the orthorhombic phase of LuFeO3, h...
Strong spin-lattice coupling and prominent frustration effects observed in the 50% Fe-doped frustrat...
Hexagonal LuFeO3 films have been studied using x-ray absorption and optical spectroscopy. The crysta...
Strong spin-lattice coupling and prominent frustration effects observed in the 50% Fe-doped frustrat...
Hexagonal manganites of the type \textit{R}MnO3 are well known examples of single-phase multiferroic...
To tune the magnetic properties of hexagonal ferrites, a family of magnetoelectric multiferroic mate...
Interface materials offer a means to achieve electrical control of ferrimagnetism at room temperatur...
Using combined theoretical and experimental approaches, we studied the structural and electronic ori...
The hexagonal phase of LuFeO3 is a rare example of a multiferroic material possessing a weak ferroma...
We report on the magnetic structure and ordering of hexagonal LuFeO3 films of variable thickness gro...
The structural, electric, and magnetic properties of bulk hexagonal LuFeO3 are investigated. Single ...
The crystal and magnetic structures of single-crystalline hexagonal LuFeO3 films have been studied u...
The crystal and magnetic structures of single-crystalline hexagonal LuFeO3 films have been studied u...
To tune the magnetic properties of hexagonal ferrites, a family of magnetoelectric multiferroic mate...
Strong spin-lattice coupling and prominent frustration effects observed in the 50 Fe-doped frustrate...
The structural transition at about 1000°C, from the hexagonal to the orthorhombic phase of LuFeO3, h...
Strong spin-lattice coupling and prominent frustration effects observed in the 50% Fe-doped frustrat...
Hexagonal LuFeO3 films have been studied using x-ray absorption and optical spectroscopy. The crysta...
Strong spin-lattice coupling and prominent frustration effects observed in the 50% Fe-doped frustrat...
Hexagonal manganites of the type \textit{R}MnO3 are well known examples of single-phase multiferroic...
To tune the magnetic properties of hexagonal ferrites, a family of magnetoelectric multiferroic mate...
Interface materials offer a means to achieve electrical control of ferrimagnetism at room temperatur...