Effect of carbon doping on microstructure, electronic and magnetic properties of Cr:AlN films

In this work, we have doped carbon into Cr:AlN and got two main results. First, we have found that doping small fraction of carbon will enhance magnetism significantly. This may be useful for designing new diluted magnetic semiconductors (DMS) materials and devices. Second, carbon doping modulated e...

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Bibliographic Details
Published in:Journal of alloys and compounds 2011-01, Vol.509 (2), p.440-446
Main Authors: Zeng, F., Chen, C., Fan, B., Yang, Y.C., Yang, P.Y., Luo, J.T., Pan, F., Yan, W.S.
Format: Article
Language:English
Subjects:
Alternating current
Carbon
Carbon content
Chromium
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Doping
Electrical properties of specific thin films
Electrical resistivity
Electronic structure and electrical properties of surfaces, interfaces, thin films and low-dimensional structures
Electronic transport
Exact sciences and technology
Iii-v semiconductors
Magnetic films and multilayers
Magnetic measurements
Magnetic properties
Magnetic properties and materials
Magnetic properties of monolayers and thin films
Magnetic properties of surface, thin films and multilayers
Microstructure
NEXAFS
Physics
Semiconductors
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Summary:In this work, we have doped carbon into Cr:AlN and got two main results. First, we have found that doping small fraction of carbon will enhance magnetism significantly. This may be useful for designing new diluted magnetic semiconductors (DMS) materials and devices. Second, carbon doping modulated electric resistivity significantly. This attracts our further interest in the recent background of resistive memory device. Carbon was doped into Cr:AlN films. Microstructure analysis demonstrated that the Cr atom kept at AlN lattice when carbon content was lower. The doped carbon atoms formed graphite phases and C–N clusters dispersing in the films, which influenced the electric and magnetic properties significantly. When the resistivity was around 10 5–10 7 Ω cm under an alternating current (AC) frequency of 210 Hz, it increased with increasing carbon content, and when the resistivity was around 10 3 Ω cm under a higher AC frequency of 800 kHz, it decreased with increasing carbon content. The magnetisms for the carbon-doped samples are stronger than those of samples without carbon doping. The atomic magnetic moment (AMM) of the sample with a carbon content of 2.3 at.% was the highest (0.4 μ B/Cr). It was proposed that atomic migration of carbon might have occurred under high AC frequency. The formation of C–N compounds could consume part of the available nitrogen and then increased the density of N vacancy in the Cr:AlN lattice, which is favorable for coupling among bound magnetic polarons (BMP).
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2010.09.052