P. G. Ivanov scite author profile

We report a systematic study of the spin polarization of epitaxial CrO2 films at and across an interface using planar junctions with a superconducting counterelectrode. By chemical modification of the CrO2 surface before the deposition of the superconductor, junctions with a wide range of barrier strength were obtained. Analysis of the conductance data on these junctions, especially under Zeeman splitting of the superconducting density of states, yields consistent, close to full spin polarization for CrO2 regardless of the barrier strength.

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Epitaxial growth of CrO2 thin films by chemical-vapor deposition from a Cr8O21 precursor

Ivanov¹,

Watts²,

Lind³

2001

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Presently, the best epitaxial thin films of CrO2 are made by chemical-vapor deposition (CVD) in a two-zone furnace with oxygen flow from a CrO3 precursor. The growth mode has previously been described as CrO3 vaporizing in the first zone, and thermally decomposing at higher temperature in the second zone onto a substrate. In the more recent works, the focus has been on the properties of the obtained layers rather than on deposition mechanisms. In the present experimental work, we attack the epitaxial growth of CrO2 by two completely different methods, namely, molecular-beam epitaxy (MBE) and CVD. We focus on the CVD process itself, and show the importance of an intermediate compound, Cr8O21, for the growth of CrO2 films. We show that it is not necessary to start the CVD from CrO3; instead, one can prepare Cr8O21 ex situ, and use it directly for the growth of high-quality CrO2 epitaxial layers, avoiding any contamination caused by the decomposition of CrO3 to Cr8O21. We discuss in parallel our failed attempts to deposit CrO2 from either CrO3 or Cr and oxygen plasma by MBE and our experiments with the CVD process, and conclude that CrO3 does not decompose directly to CrO2 and oxygen, as was expected. We propose a hypothesis that the role of Cr8O21 in the CVD process is to exude unstable molecules of CrO4, and that the reaction on the substrate is the decomposition CrO4→CrO2+O2.

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Large inverse magnetoresistance ofCrO2∕Cojunctions with an artificial barrier

et al. 2004

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We report on magnetotransport measurements on magnetic junctions consisting of Co and half-metallic CrO 2 as the electrodes. The insulating barrier in between is a CrO x -AlO x layer created via a chemical modification of the native CrO 2 surface, followed by the deposition and oxidation of a thin Al layer. The junctions exhibit a hysteretic low-field magnetoresistance with switching closely matching that of the magnetization of the CrO 2 and Co layers. The magnetoresistance is inverse in sign, with a maximum value of −24% at 5 K, implying a negative spin polarization for Co in such structures. The magnetoresistance shows strong temperature and bias dependence, diminishing quickly with increasing temperature and bias voltage.

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Detection of field-dependent antiferromagnetic domains in exchange-biased Fe3O4/NiO superlattices

Borchers

Ijiri

Lind

et al. 2000

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Neutron diffraction studies of Fe3O4/NiO superlattices reveal that the field dependence of domains in the antiferromagnetic NiO is correlated with the presence or absence of exchange biasing. Measurements of the full width at half maximum of the (111) NiO reflection show that after cooling in zero field, the antiferromagnetic domain size both parallel and perpendicular to the growth axis is sensitive to the strength of the applied field. In contrast, after cooling from room temperature in a field of 5 T, the domain size is generally smaller than the zero-field-cooled value and does not vary with field. These data suggest that exchange biasing originates from domain walls frozen into the antiferromagnet upon field cooling.

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Low-loss SAW filters using new SPUDT structures

Chvets¹,

Ivanov²,

Makarov³

et al.

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P. G. Ivanov

Spin Polarization ofCrO2at and across an Artificial Barrier

Epitaxial growth of CrO2 thin films by chemical-vapor deposition from a Cr8O21 precursor

Large inverse magnetoresistance ofCrO2∕Cojunctions with an artificial barrier

Detection of field-dependent antiferromagnetic domains in exchange-biased Fe3O4/NiO superlattices

Low-loss SAW filters using new SPUDT structures

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