no. 60. n. boshkov, “galvanic zn-mn alloys...
TRANSCRIPT
С П И С Ъ К
от забелязани цитати на научните трудове на д-р Николай Стоянов Божков
No. 60. N. Boshkov, “Galvanic Zn-Mn alloys - electrodeposition, phase composition, corrosion
behaviour and protective ability”, Surface and Coatings Technology, 172, 2-3, 217-226, 2003.
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2. Close, D., Stein, N., Allain, N., Tidu, A., Drynski, E., Merklein, M., Lallement, R.,
“Electrodeposition, microstructural characterization and anticorrosive properties of Zn-Mn alloy
coatings from acidic chloride electrolyte containing 4-hydroxybenzaldehyde and ammonium
thiocyanate”, (2016), Surface and Coatings Technology, 298, 73-82.
3. Close, D., Stein, N., Allain, N., Tidu, A., Drynski, E., Merklein, M., Lallement, R.,
“Electrodeposition, microstructural characterization and anticorrosive properties of Zn-Mn alloy
coatings”, (2016), MA2016-01, 229-th ECS Meeting, San Diego, CA, Meeting Abstract.
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“Effect of pH values on the characterization of electrodeposited Zn-Mn coatings in chloride-based
acidic environment”, (2015), International Journal of Electrochemical Science, 10, (6), 4513-4522.
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19. Zhongbao F., Qingyang L., Jingiu Z., Peixia Y., Maozhong A., “Studies on the enhanced
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20. Ahmido A., El Hajaji S., Ouaki B., Sabbar A., Sebbahi S., “Corrosion behavior of Sn-9Zn-
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21. Assaf H.F., Abou-Krisha M.M., Alduaij O.K., El-Seidy A.M.A., Eissa A.A., “The Effect
Manganese Concentration on the Corrosion Resistance and Physical Properties of Zn-Ni-Mn Alloy
Films Produced by Electrodeposition”, (2015), International Journal of Electrochemical Science, 10,
6273 – 6287.
22. Wang, Y., Zeng, J., “Effects of manganese addition on microstructures and corrosion
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23. Ganesan, S., Prabhu, G., Popov, B., “Electrodeposition and characterization of Zn-Mn
coatings for corrosion protection”, (2014) Surface and Coatings Technology, 238, 143-151.
24. Wykpis, K., Bierska-Piech, B., Kubisztal, J., “Electrodeposition of Zn-Mn coatings from a
sulphate bath in the presence of complexing additives”, (2014), Surface and Interface Analysis, 46, (10-
11), 740-745.
25. Boonyongmaneerat, Y., Saengkiettiyut, K., Saenapitak, S., Sangsuk, S., “Corrosion behavior
of reverse-pulse electrodeposited Zn-Ni alloys in saline environment”, (2014), Journal of Materials
Engineering and Performance, 23, (1), 302-307.
26. Li, W.-P., Zuo, X.-L., Liang, J.-H., He, J.-H., Zhang, S.-T., “Effect of acetate on
electrodeposition of manganese from chloride electrolyte with SeO2 additives”, (2014), Advanced
Materials Research, 937, 193-199.
27. Ranganatha, S., Venkatesha, T.V., “Fabrication and electrochemical characterization of Zn-
halloysite nanotubes composite coatings”, (2014), RSC Advances, 4, (59), 31230-31238.
28. Rafiee, A., Raeissi, K., Golozar, M.A., “Characterisation and corrosion resistance of Zn-Mn
coatings electrodeposited from acidic chloride bath”, (2014), Transactions of the Institute of Metal
Finishing, 92, (2), 115-120.
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29. Marín-Sánchez, M., Ocón, P., Conde, A., García, I., “Electrodeposition of Zn-Mn coatings on
steel from 1-ethyl-3-methylimidazolium bis (trifluoromethanesulfonyl) imide ionic liquid”, (2014),
Surface and Coatings Technology, 258, 871-877.
30. Rosalbino, F., Scavino, G., Macciò, D., Saccone, A., “Influence of the alloying component on
the corrosion behaviour of zinc in neutral aerated sodium chloride solution”, (2014), Corrosion
Science, 89, (C), 286-294.
31. Maclej A., Simka W., Nawrat G., Dercz G., “Badania wstępne nad anodowym utlenianiem
galwanicznych powłok stopowych Zn-Ni oraz charakterystyka korozyjna wytworzonych powłok
tlenkowych”, (“Preliminary studies on the anodic oxidation of galvanic coatings Zn-Ni and
characteristics of corrosion produced oxide coatings”), (2014), Ochrona przed Korozja, 5, 168-173.
32. Wykpis K., Niedbala J., Kubisztal J., Bierska-Piech B., “Otrzymywanie elektrolitycznych
powłok Zn-Mn w obecności związków kompleksujących”, (“Preparation of electrolytic Mn-Zn in the
presence of complexing agents”), (2014), Rudy i Metale Niejelazne Recycling, 59, 11, 533 – 536.
33. Nayana, K.O., Venkatesha, T.V., Chandrappa, K.G., “Influence of additive on
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Technology, 235, 461-468.
34. Bučko, M., Lačnjevac, U., Bajat, J., “The influence of substituted aromatic aldehydes on the
electrodeposition of Zn-Mn alloy”, (2013), Journal of the Serbian Chemical Society, 78, (10), 1569-
1581.
35. Bučko, M., Rogan, J., Stevanović, S.I., Stanković, S., Bajat, J.B., “The influence of anion
type in electrolyte on the properties of electrodeposited ZnMn alloy coatings”, (2013), Surface and
Coatings Technology, 228, 221-228.
36. Sun, H., Liu, S., Sun, L., “A comparative study on the corrosion of galvanized steel under
simulated rust layer solution with and without 3.5wt% NaCl”, (2013), International Journal of
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processes of HVOF Inconel 625, CoNiCrAIY and WCCoCr coatings”, (2013), PhD Thesis, University
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galwanicznej w procesie elektroosadzania powłok Zn-Mn”, (“Optimization of the chemical
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Mn obtained in the chloride bath”), (2013), Inzynieria Powierzchni, 4, 39-44.
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coatings”, (2012), ECS Transactions, 50, (31), 405-424.
43. Ranganatha, S., Venkatesha, T.V., Vathsala, K., Kumar, M.K.P., “Electrochemical studies on
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49. Zhan Guo-liang, Luo Jian-cheng, Mo Ye-giang, Ma Chong, Zuo Zheng-xun, Li Wei-shan,
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50. Popczyk M., Wykpis K., “Właściwości korozyjne powłok Zn-Mn elektroosadzanych w
kąpieli siarczanowej zawierającej tiomocznik”, (“Corrosion properties of electyrodeposited Zn-Mn
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pirofosfatnog elektrolita”), (2011) Hemijska Industrija, 65 (3), 295-303.
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magnesium alloy in ZnF2 solution”, (2011), Advanced Materials Research, 146-147, 1390-1397.
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1. Touazi, S., Bucko, M., Makhloufi, L., Legat, A., Bajat, J.B., “The electrochemical behavior
of Zn-Mn alloy coating in carbonated concrete solution”, (2016), Surface Review and Letters, 23, (4),
art. No. 1650030.
2. Tafreshi M., Allahkaram S.R., Farhangi H., “Comparative study on structure, corrosion
properties and tribological behavior of pure Zn and different Zn-Ni alloy coatings”, (2016), Materials
Chemistry and Physics, 183, 263-272.
3. Ji S.Y., Liang S.H., Song K.X., Li H.X., Li Z., “Effects of lanthanum on the microstructure,
electrochemical behavior, and anti-corrosion properties of zinc–copper–titanium alloy in 3% sodium
chloride solution”, (2016), Materials and Corrosion, DOI: 10.1002/maco.201609159.
4. Close, D., Stein, N., Allain, N., Tidu, A., Drynski, E., Merklein, M., Lallement, R.,
“Electrodeposition, microstructural characterization and anticorrosive properties of Zn-Mn alloy
coatings from acidic chloride electrolyte containing 4-hydroxybenzaldehyde and ammonium
thiocyanate”, (2016), Surface and Coatings Technology, 298, 73-82.
5. Close, D., Stein, N., Allain, N., Tidu, A., Drynski, E., Merklein, M., Lallement, R.,
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3. Fashu, S., Gu, C.D., Zhang, J.L., Zheng, H., Wang, X.L., Tu, J.P., “Electrodeposition,
Morphology, Composition, and Corrosion Performance of Zn-Mn Coatings from a Deep Eutectic
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No. 22. Koleva D., Boshkov N., Van Breugel K., De Wit J.H.W., “Steel corrosion resistance in
model solutions, containing waste materials”, Electrochimica Acta, 58, 1, 628 - 646, 2011
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Korrosionsgeschwindigkeit durch die Chromatfilme und ihrer Schutzfähigkeit mit Hilfe von
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1. Roev V.G., Matykina E.Y., Kaidrikov R.A., “Short-Term Assessment of Chromate Films on
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Papers presented to Cathodic Protection Conference UMIST (10-11.02.2003), Preprint 14 (1-14).
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Schorr, M., “Surface modification of carbon steel reinforcement of concrete”, (2015), Anti-Corrosion
Methods and Materials, 62, (2), 69-76.
3. Belmonte M.R., Quiroz J.T.P., Madrid M.M., Acosta A.T., “Aplicación de corriente catódica
como sistema de protección contra la corrosión de estructuras de concreto reforzado” [“Cathodic
current application as a corrosion protection system for reinforced concrete structures”], (2013),
Instituto Mexicano del Transporte, ISSN 0188-7297, 1-52.
No. 79. Raichevski G., Boschkov N., Sofianska A., Atanassov N., “Anodisches und
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No. 81. Bratoeva, M., Gurkovski, S., Boschkov, N., "Laserelektrochemie bei der Herstellung von
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No. 84. Boschkov, N., Raichevski, G., Raschkov, St., "Elektrochemische
Korrosionsuntersuchungen von chromatierten Zinküberzügen, Teil II: Bestimmung der
Korrosionsgeschwindigkeit von Chromat-filmen durch Polarisationmessungen in der Nähe des
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1. Roev V.G., Matykina E.Y., Kaidrikov R.A., “Short-Term Assessment of Chromate Films on
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2. Jelinek, T.W., “Advances in Metal Finishing – A Survey of the International Literature
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No. 80. Raichevski G., Boschkov N., Nikolova M., Raschkov St., "Einfluss der Zusammensetzung,
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(1998), Гальванотехника и обработка поверхности (Electroplating & Surface Treatment),
ВИНИТИ, Москва, 6, (2), 6-29.
No. 71. Boschkov N., Raichevski G., Atanassov N., Paul M., Friedrich S., “Verhalten von
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ВИНИТИ, Москва, 1, (2), 17-22.
No. 66. Bratoeva M., Boschkov N., Popova I., “Elektrochemische Legierungsabscheidung von
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1. Jelinek, T.W., “Advances in Metal Finishing – A Survey of the International Literature
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(2002), Гальванотехника и обработка поверхности (Electroplating & Surface Treatment),
ВИНИТИ, Москва, 1, (2), 17-22.
3. Mockute, D., Bernotiene, G., Butkiene, R., “The effect of electrolytes composition on the
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No. 70. Boschkov N., Raichevski G., Atanassov N., Klimanek P., “Anodisches und
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1. Jelinek, T.W., “Advances in Metal Finishing – A Survey of the International Literature
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2. Елинек Т.В., “Успехи Гальванотехники. Обзор мировой литературы за 2000-2001 г.”,
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ВИНИТИ, Москва , 1, (2), 17-22.
No. 68. Bratoeva M., Tzatscheva Tz., Boschkov N., Atanasssov N., “Elektrolytisch abgeschiedene
Co-W-Legierungen im Hinblick auf kompositionsmodulierte CoWx / CoWy - Multischichten”,
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1. Jelinek, T.W., “Advances in Metal Finishing – A Survey of the International Literature
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2. Елинек Т.В., “Успехи Гальванотехники. Обзор мировой литературы за 2000-2001 г.”,
(2002), Гальванотехника и обработка поверхности (Electroplating & Surface Treatment),
ВИНИТИ, Москва, 1, (2), 17-22.
No. 67. Bratoeva M., Boschkov N., Gurkovski S., Novev T., “Elektrolytische Silberabscheidung
mit Laserunterstützung”, Galvanotechnik, 92, 5, 1220 – 1224, 2001.
1. Jelinek, T.W., “Advances in Metal Finishing – A Survey of the International Literature
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51
No. 15. Bachvarov V., Peshova M., Vitkova S., Boshkov N., “Electrodeposition, structure and
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No. 28. Koleva D.A., Hu J., De Wit J.H.W., Boshkov N., Radeva Ts., Milkova V., Van Breugel K.,
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