Your search keyword '"Bazhenova, Tamara A."' showing total 3 results

1. Ten-Coordinate Lanthanide [Ln(HL)(L)] Complexes (Ln = Dy, Ho, Er, Tb) with Pentadentate N3O2-Type Schiff-Base Ligands: Synthesis, Structure and Magnetism.

Author

Bazhenova, Tamara A., Yakushev, Ilya A., Lyssenko, Konstantin A., Maximova, Olga V., Mironov, Vladimir S., Manakin, Yuriy V., Kornev, Alexey B., Vasiliev, Alexander N., and Yagubskii, Eduard B.

Subjects

RARE earth metals, MAGNETISM, CHELATING agents, SINGLE molecule magnets, DYSPROSIUM

Abstract

A series of five neutral mononuclear lanthanide complexes [Ln(HL)(L)] (Ln = Dy3+, Ho3+ Er3+ and Tb3+) with rigid pentadentate N3O2-type Schiff base ligands, H2LH (1-Dy, 3-Ho, 4-Er and 6-Tb complexes) or H2LOCH3, (2-Dy complex) has been synthesized by reaction of two equivalents of 1,1'-(pyridine-2,6-diyl)bis(ethan-1-yl-1-ylidene))dibenzohydrazine (H2LH, [H2DAPBH]) or 1,1'-(pyridine-2,6-diyl)bis(ethan-1-yl-1-ylidene))di-4-methoxybenzohydrazine (H2LOCH3, [H2DAPMBH]) with common lanthanide salts. The terbium complex [Tb(LH)(NO3)(H2O)2](DME)2 (5-Tb) with one ligand H2LH was also obtained and characterized. Single crystal X-ray analysis shows that complexes 1-4 have the composition {[Ln3+(HL)-(L)2-] solv} and similar molecular structures. In all the compounds, the central Ln3+ ion is chelated by two interlocked pentadentate ligands resulting in the coordination number of ten. Each lanthanide ion is coordinated by six nitrogen atoms and four oxygen atoms of the two N3O2 chelating groups forming together a distorted bicapped square antiprismatic polyhedron N6O4 with two capping pyridyl N atoms in the apical positions. The ac magnetic measurements reveal field-induced single-molecule magnet (SMM) behavior of the two dysprosium complexes (with barriers of Ueff = 29 K at 800 Oe in 1-Dy and Ueff = 70 K at 300 Oe in 2-Dy) and erbium complex (Ueff = 87 K at 1500 Oe in 4-Er); complex 3-Ho with a non-Kramers Ho3+ ion is SMM-silent. Although 2-Dy differs from 1-Dy only by a distant methoxy-group in the phenyl ring of the ligand, their dynamic magnetic properties are markedly different. This feature can be due to the difference in long-range contributions (beyond the first coordination sphere) to the crystal-field (CF) potential of 4f electrons of Dy3+ ion that affects magnetic characteristics of the ground and excited CF states. Magnetic behavior and the electronic structure of Ln3+ ions of 1-4 complexes are analyzed in terms of CF calculations. [ABSTRACT FROM AUTHOR]

Published

2020

2. A Series of Novel Pentagonal-Bipyramidal Erbium(III) Complexes with Acyclic Chelating N 3 O 2 Schiff-Base Ligands: Synthesis, Structure, and Magnetism.

Author

Bazhenova, Tamara A., Kopotkov, Vyacheslav A., Korchagin, Denis V., Manakin, Yuriy V., Zorina, Leokadiya V., Simonov, Sergey V., Yakushev, Ilya A., Mironov, Vladimir S., Vasiliev, Alexander N., Maximova, Olga V., and Yagubskii, Eduard B.

Subjects

*SINGLE molecule magnets, *MAGNETISM, *ERBIUM, *MAGNETIC measurements, *MAGNETIC properties, *LIGANDS (Biochemistry), *ERBIUM compounds

Abstract

A series of six seven-coordinate pentagonal-bipyramidal (PBP) erbium complexes, with acyclic pentadentate [N3O2] Schiff-base ligands, 2,6-diacetylpyridine bis-(4-methoxybenzoylhydrazone) [H2DAPMBH], or 2,6-diacethylpyridine bis(salicylhydrazone) [H4DAPS], and various apical ligands in different charge states were synthesized: [Er(DAPMBH)(C2H5OH)Cl] (1); [Er(DAPMBH)(H2O)Cl]·2C2H5OH (2); [Er(DAPMBH)(CH3OH)Cl] (3); [Er(DAPMBH)(CH3OH)(N3)] (4); [(Et3H)N]+[Er(H2DAPS)Cl2]− (5); and [(Et3H)N]+[Y0.95Er0.05(H2DAPS)Cl2]− (6). The physicochemical properties, crystal structures, and the DC and AC magnetic properties of 1–6 were studied. The AC magnetic measurements revealed that most of Compounds 1–6 are field-induced single-molecule magnets, with estimated magnetization energy barriers, Ueff ≈ 16–28 K. The experimental study of the magnetic properties was complemented by theoretical analysis based on ab initio and crystal field calculations. An experimental and theoretical study of the magnetism of 1–6 shows the subtle impact of the type and charge state of the axial ligands on the SMM properties of these complexes. [ABSTRACT FROM AUTHOR]

Published

2021

3. Variation of color of magnetic noise in Er3+ molecular magnets contacting metal surface in ferromagnetic composite.

Author

Kunitsyna, Ekaterina I., Talantsev, Artem D., Bazhenova, Tamara A., Yagubskii, Eduard B., Chernov, Alexander I., and Morgunov, Roman B.

Subjects

*MAGNETIC noise, *SINGLE molecule magnets, *MAGNETIC declination, *METALLIC surfaces, *FERROMAGNETIC materials, *SUPERCONDUCTING magnets

Abstract

[Display omitted] • Strategy of molecular magnets functionalization inside a ferromagnetic media is proposed. • Residual field of the microparticle arrays affects frequency of magnetic relaxation. • Chemical bond between SMM and the microparticles surface changes relaxation frequency. • Color of magnetic noise depends on physical origin of magnetic relaxation. • Chemically designed spin interface is convenient for spintronics and quantum computing. Interaction between single molecule magnets (SMMs) and metal surface is a hot topic promising controllable deposition of SMMs, programmable frequency of magnetic relaxation and addressed reading of information. In this paper, we develop strategy of the Er3+ based SMM functionalization by its penetration inside the arrays of Ferromagnetic Micro Particles (FMPs). We show that predictable residual magnetic field of the FMPs arrays is an effective tool for regulation of the frequency maximum of imaginary magnetic susceptibility. We analyzed color of magnetic noise in respect to physical origin of magnetic relaxation. An additional channel for control over spin noise is formation of chemical bonds between SMM and the FMPs surface. Oxidation of an Er complex transforms 20 ± 5 % of the initial 10-coordinated SMM complex to the 9-coordinated complex with reduced relaxation time. Memorized residual magnetization of the composite material allows one to set desirable relaxation frequency in the individual micronized cells to create a sound frequency register. The proposed compaction of SMMs of different types in ferromagnetic composites provides engineering of the chemically designed spin interface on ferromagnetic surface for spintronics and quantum computing. [ABSTRACT FROM AUTHOR]

Published

2024