Your search keyword '"Lyubutin, Igor S."' showing total 3 results

1. Crystal structure of bismuth-containing NdFe 3 (BO 3 ) 4 in the temperature range 20-500 K.

Author

Smirnova ES, Alekseeva OA, Dudka AP, Verin IA, Artemov VV, Lyubutina MV, Gudim IA, Frolov KV, and Lyubutin IS

Subjects

Crystallography, X-Ray, Neodymium, Temperature, Bismuth, Iron

Abstract

Neodymium iron borate NdFe 3 (BO 3 ) 4 is an intensively studied multiferroic with high electric polarization values controlled by a magnetic field. It is characterized by a large quadratic magnetoelectric effect, rigidity in the base plane and a rather strong piezoelectric effect. In this work, the atomic structure of (Nd 0.91 Bi 0.09 )Fe 3 (BO 3 ) 4 was studied by single-crystal X-ray diffraction in the temperature range 20-500 K (space group R32, Z = 3). The Bi atoms found in the composition partially substitute the Nd atoms in the 3a position; they entered the structure due to the growth conditions in the presence of Bi 2 Mo 3 O 12 . It was shown that in the temperature range 20-500 K there is no structural phase transition R32→P3 1 21, which occurs in rare-earth iron borates (RE = Eu-Er, Y) with an effective rare-earth cation radius smaller than that of Nd. The temperature dependence of the unit-cell c parameter reveals a slight increase on cooling below 90 K, which is similar to the results obtained previously for iron borates of Gd, Y and Ho. The atomic distances (Nd,Bi)-O, (Nd,Bi)-B, (Nd,Bi)-Fe, Fe-O, Fe-B and Fe-Fe in the iron chains and between chains decrease steadily with decreasing temperature from 500 to 90 K, whereas the B1(3b)-O distance does not change and the average B2(9e)-O distance increases slightly. There is a uniform decrease in the atomic displacement parameters with decreasing temperature, with a more pronounced decrease for the Nd(3a) and O2(9e) atoms. The O2(9e) atoms are characterized by the maximum atomic displacement parameters and the most elongated atomic displacement ellipsoids. The characteristic Debye and Einstein temperatures, and the static component in the atomic displacements were determined for cations using multi-temperature diffraction data. It was shown that the Nd cations have the weakest bonds with the surrounding atoms and the B cations have the strongest.

Published

2022

2. Crystal structure of bismuth‐containing NdFe3(BO3)4 in the temperature range 20–500 K.

Author

Smirnova, Ekaterina S., Alekseeva, Olga A., Dudka, Alexander P., Verin, Igor A., Artemov, Vladimir V., Lyubutina, Marianna V., Gudim, Irina A., Frolov, Kirill V., and Lyubutin, Igor S.

Subjects

CRYSTAL structure, ATOMIC displacements, MAGNETOELECTRIC effect, PIEZOELECTRICITY, ATOMIC structure, BISMUTH, IRON

Abstract

Neodymium iron borate NdFe3(BO3)4 is an intensively studied multiferroic with high electric polarization values controlled by a magnetic field. It is characterized by a large quadratic magnetoelectric effect, rigidity in the base plane and a rather strong piezoelectric effect. In this work, the atomic structure of (Nd0.91Bi0.09)Fe3(BO3)4 was studied by single‐crystal X‐ray diffraction in the temperature range 20–500 K (space group R32, Z = 3). The Bi atoms found in the composition partially substitute the Nd atoms in the 3a position; they entered the structure due to the growth conditions in the presence of Bi2Mo3O12. It was shown that in the temperature range 20–500 K there is no structural phase transition R32→P3121, which occurs in rare‐earth iron borates (RE = Eu–Er, Y) with an effective rare‐earth cation radius smaller than that of Nd. The temperature dependence of the unit‐cell c parameter reveals a slight increase on cooling below 90 K, which is similar to the results obtained previously for iron borates of Gd, Y and Ho. The atomic distances (Nd,Bi)—O, (Nd,Bi)—B, (Nd,Bi)—Fe, Fe—O, Fe—B and Fe—Fe in the iron chains and between chains decrease steadily with decreasing temperature from 500 to 90 K, whereas the B1(3b)—O distance does not change and the average B2(9e)—O distance increases slightly. There is a uniform decrease in the atomic displacement parameters with decreasing temperature, with a more pronounced decrease for the Nd(3a) and O2(9e) atoms. The O2(9e) atoms are characterized by the maximum atomic displacement parameters and the most elongated atomic displacement ellipsoids. The characteristic Debye and Einstein temperatures, and the static component in the atomic displacements were determined for cations using multi‐temperature diffraction data. It was shown that the Nd cations have the weakest bonds with the surrounding atoms and the B cations have the strongest. [ABSTRACT FROM AUTHOR]

Published

2022

3. Crystal structure and structural phase transition in bismuth‐containing HoFe3(BO3)4 in the temperature range 11–500 K.

Author

Smirnova, Ekaterina S., Alekseeva, Olga A., Dudka, Alexander P., Khmelenin, Dmitry N., Frolov, Kirill V., Lyubutina, Marianna V., Gudim, Irina A., and Lyubutin, Igor S.

Subjects

PHASE transitions, CRYSTAL structure, BISMUTH, ATOMIC displacements, CRYSTAL symmetry, SPACE groups, POLYHEDRA

Abstract

An accurate single‐crystal X‐ray diffraction study of bismuth‐containing HoFe3(BO3)4 between 11 and 500 K has revealed structural phase transition at Tstr = 365 K. The Bi atoms enter the composition from Bi2Mo3O12‐based flux during crystal growth and significantly affect Tstr. The content of Bi was estimated by two independent methods, establishing the composition as (Ho0.96Bi0.04)Fe3(BO3)4. In the low‐temperature (LT) phase below Tstr the (Ho0.96Bi0.04)Fe3(BO3)4 crystal symmetry is trigonal, of space group P3121, whereas at high temperature (HT) above 365 K the symmetry increases to space group R32. There is a sharp jump of oxygen O1 (LT) and O2 (LT) atomic displacement parameters (ADP) at Tstr. O1 and O2 ADP ellipsoids are the most elongated over 90–500 K. In space group R32 specific distances decrease steadily or do not change with decreasing temperature. In space group P3121 the distortion of the polyhedra Ho(Bi)O6, Fe1O6 and Fe2O6, B2O3 and B3O3 increases with decreasing temperature, whereas the triangles B1O3 remain almost equilateral. All BO3 triangles deviate from the ab plane with decreasing temperature. Fe–Fe distances in Fe1 chains decrease, while distances in Fe2 chains increase with decreasing temperature. The Mössbauer study confirms that the FeO6 octahedra undergo complex dynamic distortions. However, all observed distortions are rather small, and the general change in symmetry during the structural phase transition has very little influence on the local environment of iron in oxygen octahedra. The Mössbauer spectra do not distinguish two structurally different Fe1 and Fe2 positions in the LT phase. The characteristic temperatures of cation thermal vibrations were calculated using X‐ray diffraction and Mössbauer data. [ABSTRACT FROM AUTHOR]

Published

2019