Page 318 - DISS_NYRKOVA
P. 318
318
204.Sridhar N., Dunn D. S., Seth M. Application of a general reactive
transport model to predict environment under disbonded coatings. Corrosion.
2001. Vol. 57. № 7. P. 598–613.
205. Stress corrosion of pipeline steel under occluded coating
disbondment in a red soil environment / M. Yan et al. Corrosion Science. 2015.
Vol. 93. P. 27–38.
206. Yan M., Wang J., Han E., Ke W. Local environment under simulated
disbonded coating on steel pipelines in soil solution. Corrosion Science. 2008.
Vol. 50. № 5. P. 1331–1339.
207. Stress corrosion of pipeline steel under disbonded coating in a SRB-
containing environment. Wu T. et al. Corrosion Science. 2019. Vol. 157.
P. 518-530.
208. Beavers J.A., Harle B.A. Mechanisms of high-pH and near-neutral-
pH SCC of underground pipelines. In International Pipeline Conference. 1996.
June. Vol. 40207. P. 555 - 564.
209. Mélot D., Paugam G., Roche M. Disbondments of pipeline coatings
and their effects on corrosion risks. Journal of Protective Coatings & Linings.
2009. P. 18–31.
210. Fatehi A., Eslami A., Golozar M. A., Raeissi K., Ashari R. Cathodic
protection under a simulated coating disbondment: Effect of sulfate-reducing
bacteria. Corrosion. 2019. Vol. 75. № 4. P. 417–423.
211. Mahdavi F., Forsyth M., Tan M. Y. J. Understanding the effects of
applied cathodic protection potential and environmental conditions on the rate of
cathodic disbondment of coatings by means of local electrochemical
measurements on a multi-electrode array. Progress in Organic Coatings. 2017.
Vol. 103. P. 83–92.
212. Симионеску К., Опреа К. Механохимия высокомолекулярных
соединений : пер. з рум., 2 изд. М.: Мир. 1970. 360 с.
213. Барамбойм Н. К. Механохимия высокомолекулярных
соединений. Монография/ Изд. 3-е, перераб. и доп. М.: Химия. 1978. 384 с.
