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Synthesis and Thermoelectric Properties of NaxCo2O4 Single Crystals

Published online by Cambridge University Press:  01 February 2011

Jian He
Affiliation:
[email protected], Clemson University, Physics and Astronomy, 118 Kinard Physics Lab, Clemson, SC, 29634, United States, 1-864-6564597, 1-864-6560805
Kelvin Aaron
Affiliation:
[email protected], Clemson University, Physics and Astronomy, United States
Edward Abbott
Affiliation:
[email protected], Clemson University, Chemistry, United States
Joseph Kolis
Affiliation:
[email protected], Clemson University, Chemistry, United States
Terry M. Tritt
Affiliation:
[email protected], Clemson University, Physics and Astronomy, United States
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Abstract

Single crystal NaCo2O4 platelets with sizes up to 6mm were synthesized by the typical high temperature NaCl flux method. The in-plane thermopower α and in-plane resistivity ρ were measured to be ∼100µV/K and 0.3mΩ-cm at 300K, respectively. The in-plane thermal conductivity κ was measured by our custom-designed “PTC” system and found to be ∼5 W-m−1K−1 at 300K, which is 2-3 times larger than the polycrystalline NaCo2O4. The in-plane phonon mean free path lph was estimated to be ∼9.5Å, which is much smaller than the in-plane mean free path of conducting carriers (la∼51Å). A novel low temperature flux method where NaCl/NaOH was used as flux and metallic Co powders as Co source was developed to successfully synthesize Na-deficient NaxCo2O4 crystals with size up to 6mm at low temperature of 550°C. The different temperature dependence in resistivity reveals that two different types of crystals can exist, one is metallic and another is semiconducting. The temperature dependence of the measured k is like that of a disordered solid and the value is found to be ∼7 W-m−1K−1 at 300K.

Type
Research Article
Copyright
Copyright © Materials Research Society 2006

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References

REFERENCES

[1] Terasaki, I., Sasago, Y. and Uchinokura, K., Phys. Rev. B 56, 12685 (1997).Google Scholar
[2] Wang, Y., Rogado, N. S., Cava, R. J. and Ong, N. P., Nature, 423(22), 425 (2003).Google Scholar
[3] Fujita, K., Mochida, T., and Nakamura, K., Jpn. J. Appl. Phys. part1 40, 4644 (2001).Google Scholar
[4] Tang, Xiaofeng, Abbott, Ed, Aaron, Kelvin et al. , ICT 2005 proceedings, Clemson (2005).Google Scholar
[5] Pope, A. L., Littleton, R. T. and Tritt, T. M., Rev. Sci. Instr. 72, 3129 (2001).Google Scholar
[6] Pope, A. L., Zawilski, B. M. and Tritt, T. M., Cryogenics 41, 725 (2001).Google Scholar
[7] Zawilski, B. M., Littleton, R. T., Tritt, T. M., Rev. Sci. Instr., 72, 1770 (2001).Google Scholar
[8] Aaron, Kelvin. Master thesis. Clemson University (2005).Google Scholar
[9] Satake, A., Tanaka, H., Ohkawa, T. et al. , J. Appl. Phys., Vol. 96, 931 (2004).Google Scholar
[10] Takahata, K., Iguchi, Y., Tanaka, D. et al. Phys. Rev. B, 61 (19), 12551 (2000).Google Scholar
[11] Koshibae, W., Tsutsui, K. and Maekawa, S.. Phys. Rev. B, 62(11), 6869 (2000).Google Scholar
[12] Tang, Xiaofeng, Abbott, Edward, Aaron, Kelvin, Kolis, Joseph W., Tritt, Terry M.. Paper in preparation.Google Scholar