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Image Based Analysis of Complex Microstructures of Engineering Materials

-753. Jensen E.B. and Gundersen H.J.G. (1982). Stereological ratio estimation based on counts from integral test systems, Journal of Microscopy 125 : 51-66. Kurzydłowski K.J. and Ralph B. (1995): The Quantitative Description of the Microstructure of Materials , CRC Press, London. Spychalski W.L., Kurzydłowski K.J. and Ralph B. (2002). Computer study of inter- and intragranular surface cracks in brittle polycrystals, Materials Characterization 49 (9): 45-53. Kril C.E. and Birringer R. (1998

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Studies on the Microstructure of Epoxy-Cement Composites

References 1. P. Łukowski, “Material modification of concrete” (in Polish), SPC - Polski Cement, Cracow, 2016. 2. E. Horszczaruk, P. Brzozowski, “Bond strength of underwater repair concretes under hydrostatic pressure”, Construction and Building Materials, 72: 167-173, 2014. 3. T. Zdeb, J. Śliwiński, „The influence of selected material and technological factors on mechanical properties and microstructure of reactive powder concrete (RPC)“, Archives of Civil Engineering, LVII, 2: 227-246, 2011. 4

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Effect of Chemical Composition and Microstructure on Mechanical Properties of BA1055 Bronze Sand Castings

1962. BS1400:1985 Copper alloy ingot and copper alloy and high conductivity copper castings. Al-Hashem A., Raid W.: The role of microstructure of Ni-Al- bronze alloy on its cavitation corrosion behavior in natural seawater. Materials Characterization 48, 2002, 37-41.

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Microstructure Characterization by Means of X-ray Micro-CT and Nanoindentation Measurements

References [1] HENRY M., DARMA I.S., SUGIYAMA T., Analysis of the effect of heating and re-curing on the microstructure of highstrength concrete using X-ray CT, Construction and Building Materials, 2014, Vol. 67, 37-46. [2] REN W., YANG Z., SHARMA R., ZHANG C., WITHERS P.J., Two-dimensional X-ray CT image based meso-scale fracture modelling of concrete, Engineering Fracture Mechanics, 2015, Vol. 133, 24-39. [3] BOSSA N., CHAURAND P., VICENTE J., BORSCHNECK D., LEVARD C., AGUERRE-CHARIOL O., ROSE J., Micro- and

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Degradation of Microstructure and Mechanical Properties of 15HM Steel after 420 000 Hours of Service

. Perform., 16, (2007), 80-85. 8. Nguyen T. D., Sawada K., Kushima H., Tabuchi M., Kimura K.: Change of precipitation free zone during long - term creep in 2.25Cr-1Mo steel, Mater. Sc. Eng. A, 591A (2014), 130-135. 9. Golański G., Pietryka I., Słania J., Jasak J., Urbańczyk P., Microstructure and mechanical properties of welded joint of 12HMF steel after long - term service [in Polish], Welding Technology Review [Przegląd Spawalnictwa], 5, 2014, 49-53. 10. Joarder A., Sarma D. S., Cheruvu N. S.: Effect of long - term service

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Impact of Accelerated Carbonation on Microstructure and Phase Assemblage

pastes carbonated at different CO 2 concentrations,” Materials and Structures , Vol. 42, 2009, pp. 515-25. 4. Auroy M, Poyet S, P. LB, Torrenti J-M, Charpentier T & Moskura M: “Representativeness of accelerated carbonation testing of cement pastes,” Proceedings , XXII Nordic Concrete Research Symposia, Reykjavik, Iceland, 2014, pp. 447-450. 5. Auroy M, Poyet S, Le Bescop P, Torrenti J-M, Charpentier & T, Moskura M: “Comparison between natural and accelerated carbonation (3% CO 2 ): Impact on mineralogy, microstructure, water retention and cracking

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Microstructure Characteristics of Borated Austenitic Stainless Steel Welds

effects on weld metal microstructure and liquation cracking susceptibility of 304B4 SS joined E 309 electrode. Journal of Manufacturing Processes, 34, pp. 540-554. 7. M. DOMÁNKOVÁ, K. BÁRTOVÁ, PASTIER, P. 2017. Aging precipitation behaviour of Cr-Mn-N austenitic stainless steels. Materials Science Forum, 891, pp. 155-160.

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Microstructure and magnetic properties of Nd-Fe-B-(Re, Ti) alloys

References 1. Matsuura, Y. (2006). Recent development of Nd-Fe-B sintered magnets and their applications. J. Magn. Magn. Mater. , 303 , 344–347. DOI: 10.1016/j.jmmm.2006.01.171. 2. Leonowicz, M. (1990). Magnetic properties and microstructure of Nd 16 Fe 76−x M x B 8 magnets (M = Ga, Cr, Nb, Bi, Sn, Zr, W, V, Mo, Mn). J. Magn. Magn. Mater ., 83 , 211–213. DOI: 10.1016/0304-8853(90)90489-D. 3. Chang, H. W., Shih, M. F., Chang, C. W., Hsieh, C. C., Fang, Y. K., Chang, W. C., & Sun, A. C. (2008). Magnetic properties and micro structure of directly

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Surface condition, microstructure and microhardness of boronized layers produced on Vanadis-6 steel after modification by diode laser

Treatment, 46 (2004) 385-387. [8] Młynarczak A., Piasecki A.,Budowa i właściwości dyfuzyjnych warstw chromoborowanych wytwarzanych na stalach narzędziowych. Archiwum technologii Maszyn i Automatyzacji, 24 (2004) 173-184. [9] Wierzchoń T., Bieliński P., Sikorski K., Formation and propierties of multicomponent and composite borided layers on steel. Surface and Coatings Technology, 73 (1995) 121-124. [10] Pertek A., Kulka M., Microstructure and properties of composite (B+C) diffusion layers on low-carbon steel. Journal of

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Tooth Enamel Microstructure in Megasorex gigas (Merriam, 1897) and Cryptotis magna (Merriam, 1895) from Mexico – In Comparison to the Schmelzmuster in other Shrews

Museum of Paleontology, University of Michigan, 8(6):113–192. Hutterer, R. (2005): Soricidae. – In: Wilson, D. E., Reeder, D. M. (eds), Mammal Species of the World: A Taxonomic and Geographic Reference (3 rd ed.). Johns Hopkins University Press, pp. 267–300. Koenigswald, W. v., Clemens, W. A. (1992): Levels of complexity in the microstructure of mammalian enamel and their application in studies of systematics. – Scanning Microscopy, 6(1): 195–218. Koenigswald, W. v., Reumer, J. (2020): The enamel microstructure of fossil and extant shrews (Soricidae

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