Page 15 - Zmist-n2-2015
P. 15
5. Metallic interconnects for SOFC: Characterisation of corrosion resistance and conductivity
evaluation at operating temperature of differently coated alloys / S. Fontana, R. Amendola,
S. Chevalier et al. // J. Power Sources. – 2007. – 171. – P. 652–662.
6. Magdefrau N. J. Evaluation of solid oxide fuel cell interconnect coatings: reaction layer
microstructure, chemistry and formation mechanisms. Doctoral dissertation. – University of
Connecticut, Mansfield, USA, 2013. – P. 106.
7. Evaluation on some metallic alloys for SOFC interconnect / C. L. Chu, J. Y. Wand, J. Lee et
al. // Mater. Sci. Forum. – 2007. – 544–545. – P. 989–992.
8. A review of recent progress in coatings, surface modifications and alloy developments for
solid oxide fuel cell ferritic stainless steel interconnects / N. Shaigan, W. Qu, D.G. Ivey,
W. Chen // J. Power Sources. – 2010. – 195. – P. 1529–1542.
9. Evaluation of interconnect alloys and cathode contact coatings for SOFC stacks / N. Dekker,
th
B. Rietveld, J. Laatsch and F. Tietz // Proc. 6 European SOFC Forum. – Lucerne (Switser-
land), 28 June–2 July 2004. – P. 319–328.
10. Investigation of La 2 O 3 and/or (Co,Mn) 3 O 4 deposits on Crofer22APU for the SOFC intercon-
nect application / A. Balland, P. Gannon, M. Deibert et al. // Surf. Coat. Technol. – 2009.
– 203. – P. 3291–3296.
11. Investigation on the properties of Nb and Al doped Ti 3 SiC 2 as a new interconnect material
for IT-SOFC / L. L. Zheng, J. J. Li, M. S. Li, and Y. C. Zhou // Int. J. Hydrogen Energy.
– 2012. – № 37. – P. 1084–1088.
12. Electrical conductivity, thermopower, and Hall effect of Ti 3 AlC 2 , Ti 4 AlN 3 , and Ti 3 SiC 2 / M.
W. Barsoum, H.-I. Yoo, I. K. Polushina et al. // Phys. Rev. – 2000. – 62, № 15. – P. 1094–1098.
13. Radovic M. and Barsoum M. W. MAX phases: bridging the gap between metals and cera-
mics // Amer. Ceram. Soc. Bull. – 2013. – 92, № 3. – P. 20–27.
14. Mechanical characteristics and high temperature stability of oxidized Ti 3 AlC 2 nanolaminat
/ T. Prikhna, O. Ostash, T. Basyuk, A. Ivasyshin et al. // Proc. Int. Conf. on Oxide Mater. for
Electronic Engng. (OMEE-2014). – Lviv (Ukrain), 26–30 May 2014. – P. 81–82.
15. Study of thermal stability and mechanical characteristics of MAX-phases of Ti–Al–C(N)
system and their solid solutions / T. Prikhna, T. Cabioc’h, W. Gawalek et al. // Advan. Sci.
Technol. – 2014. – 89. – P. 123–128.
16. Патент України №94545. Жаростійкий матеріал для паливних комірок / О. П. Осташ,
Т. О. Пріхна, А. Д. Івасишин та ін. – Опубл. 25.11.14; Бюл. № 22.
17. Van der Pauw L. J. A method of measuring specific resistivity and hall effect of discs
of arbitrary shape // Philips Research Reports. – 1958. – 13. – P. 1–9.
18. High-temperature characteristics of stainless steels. Handbook (series №9004). – American
Iron and Steel Institute, 2012. – P. 47.
19. Колачев Б. А., Ливанов В. А., Буханова А. А. Механические свойства титана и его спла-
вов. – М.: Металлургия, 1974. – 544 с.
20. Diffusion of cations in chromia layers grown on iron-base alloys / R. E. Lobnig, H. P. Schmidt,
K. Hennesen, and H. J. Grabke // Oxidation of Metal. – 1992. – 37, № 1/2. – P. 81–93.
21. Oxidation-induced crack healing in Ti 3 AlC 2 ceramics / G. M. Song, Y. T. Pei, W. G. Sloof
et al. // Scripta Mater. – 2008. – 58. – P. 13–16.
22. Войтович Р. Ф., Головко Э. И. Высокотемпературное окисление титана и его спла-
вов. – К.: Наук. думка, 1984. – 256 с.
23. Effect of Nb on the high temperature oxidation of Ti–(0–50 at.%)Al / H. Jiang, M. Hirohasi,
Y. Lu, H. Imanari // Scripta Mater. – 2002. – 46. – P. 639–643.
Одержано 28.10.2014
14