Your search keyword '"Kowalski B"' showing total 3 results

1. Magnetism and magnetotransport of strongly disordered Zn1-xMnxGeAs2 semiconductor: The role of nanoscale magnetic clusters.

Author

Kilanski, L., Górska, M., Dobrowolski, W., Dynowska, E., Wójcik, M., Kowalski, B. J., Anderson, J. R., Rotundu, C. R., Maude, D. K., Varnavskiy, S. A., Fedorchenko, I. V., and Marenkin, S. F.

Subjects

MAGNETIC fields, METHACRYLONITRILE, MAGNETORESISTANCE, GALVANOMAGNETIC effects, DILUTED magnetic semiconductors, SCANNING electron microscopy, HALL effect

Abstract

We present systematic studies of magnetic and transport properties of Zn1-xMnxGeAs2 semimagnetic semiconductor with the chemical composition varying between 0.053≤x≤0.182. The transport characterization showed that all investigated samples had p-type conductivity strongly depending on the chemical composition of the alloy. The Hall effect measurements revealed carrier concentrations p≥1019 cm-3 and relatively low mobilities, μ≤15 cm2/(V s), also chemical composition dependent. The magnetic investigations showed the presence of paramagnet-ferromagnet phase transitions with transition temperatures greater than 300 K for the samples with x≥0.078. We prove by means of x-ray diffraction, nuclear magnetic resonance, and scanning electron microscopy techniques that the observed room temperature ferromagnetism is due to the presence of MnAs inclusions. The high field magnetoresistance showed the presence of giant magnetoresistance effect with maximum amplitudes around 50% due to the presence of nanosize ferromagnetic grains. [ABSTRACT FROM AUTHOR]

Published

2010

2. Anomalous Hall Effect in Ge1-x-yPbxMnyTe Composite System.

Author

Podgórni, A., Kilanski, L., Dobrowolski, W., Górska, M., Domukhovski, V., Brodowska, B., Reszka, A., Kowalski, B. J., Slynko, V. E., and Slynko, E. I.

Subjects

ANOMALOUS Hall effect, HALL effect devices, GALVANOMAGNETIC effects, GYRATORS, HALL effect

Abstract

The purpose of this study was to investigate the magnetotransport properties of the Ge0.743Pb0.183Mn0.074Te mixed crystal. The results of magnetization measurements indicated that the compound is a spin-glass-like diluted magnetic semiconductor with critical temperature TSG = 97.5 K. Nanoclusters in the sample are observed. Both, matrix and clusters are magnetically active. Resistivity as a function of temperature has a minimum at 30 K. Below the minimum a variable-range hopping is observed, while above the minimum a metallic-like behavior occurs. The crystal has high hole concentration, p = 6.6×1020 cm-3, temperature-independent. Magnetoresistance amplitude changes from –0.78 to 1.18% with increase of temperature. In the magnetotransport measurements we observed the anomalous Hall effect with hysteresis loops. Calculated anomalous Hall effect coeffcient, RS = 2.0 × 106 m3/C, is temperature independent. The analysis indicates the extrinsic skew scattering mechanism to be the main physical mechanism responsible for anomalous Hall effect in Ge0.743Pb0.183Mn0.074Te alloy. [ABSTRACT FROM AUTHOR]

Published

2014

3. ZnCoO Films by Atomic Layer Deposition - Influence of a Growth Temperature on Uniformity of Cobalt Distribution.

Author

Łukasiewicz, M. I., Witkowski, B., Godlewski, M., Guziewicz, E., Sawicki, M., Paszkowicz, W., Lusakowska, E., Jakieła, R., Krajewski, T., Kowalik, I. A., and Kowalski, B. J.

Subjects

MAGNETIC films, MAGNETIC properties of thin films, ELECTRIC properties of thin films, ZINC, COBALT, SCANNING electron microscopy, X-ray diffraction, ATOMIC force microscopy, HALL effect

Abstract

We report on the structural, electrical and magnetic properties of ZnCoO thin films grown by atomic layer deposition method using reactive organic precursors of zinc and cobalt. As a zinc precursor we applied either dimethylzinc or diethylzinc and cobalt(II) acetyloacetonate as a cobalt precursor. The use of these precursors allowed us the significant reduction of a growth temperature to 300 °C and below, which proved to be very important for the growth of uniform films of ZnCoO. Structural, electrical and magnetic properties of the obtained ZnCoO layers will be discussed based on the results of secondary ion mass spectroscopy, scanning electron microscopy, energy dispersive spectroscopy, X-ray diffraction, atomic force microscopy, Hall effect and SQUID investigations. [ABSTRACT FROM AUTHOR]

Published

2009