Physics and Chemistry of Solid State

 

2015   Vol.16   №1

Title

Content

Editorial
Board

 
 

DOI: 10.15330/pcss.16.1.49-54

D.M. Freik1, S.І. Mudriy2, Ts.A. Kriskov3, І.V. Gorіchok1, O.M. Matkіvsky1, T.O. Semko1

 Synthesis and Properties of Highly Efficient Thermoelectric Materials Based on Lead Telluride with Antimony and Silver Impurity

1Vasyl Stefanyk Prekarpathian University, Shevchenko Str., 57, Ivano-Frankivsk, 76018, Ukraine, e-mail: fcss@pu.if.ua
3Ivan Franko Lviv National University, 6, Kyryl & Mephodiy Str., Lviv, 79005
2Kamyanets-Podilsky State University, Ogienko Str. 61, Kamyanets-Podilsk, 32300, Ukraine, е-mail: fizkaf@ua.fm

The paper presents the results of research of X-ray diffraction and thermoelectric parameters (thermoelectric coefficient α, electrical conductivity σ and thermal conductivity coefficient k) of materials based on Lead Telluride: PbTe, PbTe:Sb, PbTe-Sb2Te3, Pb18Ag1Sb1Te20, Pb18Ag2Te20 and PbTe-Ag2Te. Established that the highest values of thermoelectric figure of merit have samples of PbTe:Sb (0,3 at.%) and system Pb18Ag1Sb1Te20, Pb18Ag2Te20. For PbTe:Sb is due to a significant increase of the electrical conductivity. For the other two materials is due to a increase the thermoelectric coefficient and a significant decrease of thermal conductivity compared to pure PbTe.
Keywords: Lead telluride, doping, solid solutions, LAST, thermoelectric properties.

Full text (on original language) .pdf
Home 

 Reference

[1] L.D. Borisova. Phys. stat. sol. (a). 53, K19 (1979).
[2] Chr. Jaworski, J. Tobola, E.M. Levin, Kl. Schmidt-Rohr, J. Heremans, Physical Review B. 80, 125208-1 (2009).
[3] D.M. Freїk, R.O. Dzumedzej, І.V. Gorіchok, L.І. Nikiruj, S.І. Mudrij. FHTT. 14(2), 390 (2013).
[4] D.M. Freik, C.A. Kryskov, I.V. Horichok, T.S. Lyuba, O.S. Krynytsky, O.M. Rachkovsky. Journal of Thermoelectricity. 2, 42 (2013).
[5] D.M. Freik, S.I. Mudryi, I.V. Gorichok, R.O. Dzumedzey, O.S. Krunutcky, T.S. Lyuba. Ukr. J. Phys. 59(7), 706 (2014).
[6] P.-W. Zhu, Y. Imai, Y. Isoda, Y. Shinohara, X.-P. Jia, G.-T. Zou. Chin.Phys.Lett., 22 (8), 2103 (2005).
[7] K-F. Hsu, S. Loo, F. Guo, W. Chen, J. S. Dyck, C. Uher, T. Hogan, E. K. Polychroniadis, M. G.Kanatzidis. Science, 303(5659), 818 (2004).
[8] H. Hazama, U. Mizutani. Phys. Rev. B. 73, 115108 (2006).
[9] E. Quarez, K.F. Hsu, R. Pcionek, N. Frangis, E.K. Polychroniadis, M.G. Kanatzidis. J. Am. Chem. Soc. 127, 9177 (2005).
[10] J. Sootsman, R. Pcionek, H. Kong, C. Uher, M.G. Kanatzidis. Mater. Res. Soc. Symp. Proc. 886, 0886-F08-05 (2006).
[11] D. Bilc, S.D. Mahanti, E. Quarez, K.F. Hsu, R. Pcionek, M.G. Kanatzidis. Phys. Rev. Lett. 93, 146403 (2004).
[12] D.M. Freїk, R.Ja. Mihajl'onka, V.M. Klanіchka. Fіzika і hіmіja tverdogo tіla. 5(1), 173 (2004).