Module Name: Optic Mineralogy and Petrography Code, If Applicable GL 3141 Semester(S) in Which the First Semester Module Is Taught Person Responsible for the Ir

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Module name: Optic Mineralogy and Petrography Code, if applicable GL 3141 Semester(s) in which the First Semester module is taught Person responsible for the Ir. Nurcahyo Indro Basuki, M.T., Ph.D module Lecturer Ir. Nurcahyo Indro Basuki, M.T., Ph.D Language Relation to curriculum Compulsory Course Types of Class Attendance time Forms of active Workload teaching and Size (hours per week participation per semester) learning Total Workload Credit points 3 CU Requirements according to the examination regulations Recommended 1. Crystallography and Mineralogy (Prerequisite) prerequisites 2. Petrology (Prerequisite) Module objectives/intended Students understand the optical phenomenon of rock-forming learning outcomes minerals and can identify rock-forming minerals using a polarization microscope. Students are able to distinguish and classify igneous rocks, pyroclastics, sedimentary and metamorphic mineralogy and texture as well as by interpreting it’s rock formation Content This course discusses the optical phenomenon of rock-forming minerals, especially minerals. Additionally, it will also discussed methods of recognition and identification of minerals and rocks, as well as the introduction of texture and classification of igneous rocks, pyroclastics, sedimentary and metamorphic using a polarization microscope. Some aspects that will be discussed in this course: 1. Phenomena of lights and wave in polarization microscope 2. Bowen Series Mineral optical character 3. Igneous rocks classification, texture, and mineralogy 4. Pyroclastic rocks 5. Sedimentary rocks 6. Metamorphic rocks Study and examination requirements and forms of examination Media employed Reading list 1. Adams, A.E., Mackenzie, W.S., and Guilford, C., 1984. Atlas of Sedimentary Rocks Under the Microscope. Prentice Hall, 112 p. 2. Deer, W.A, Howie, R.A, and Zussman, J., 1979. An Introduction to the Rock-Forming Minerals (2nd edition). Pearson United Kingdom. 712 p. 3. Ehlers, G.E., and Blat, H., 1982, Petrology, W.H. Freeman and Co., San Fransisco, 732 p. 4. Kerr. P.F. 1977. Optical Mineralogy, 4th ed. Mc Graw Hill Book Coy. 492 p. 5. MacKenzie, W.S. and Adams, A.E., 1994. Rocks and Minerals in Thin Section (A Colour Atlas). Manson Publishing, 192 p. 6. MacKenzie, W.S. and Guilford C., 1980. Atlas of Rock-forming Minerals in Thin Section. Prentice Hall, 104 p. 7. MacKenzie, W.S., Donaldson, C.H., and Guilford C., 1982. Atlas of Igneous Rocks and Their Textures. Wiley, 148 p. 8. Nesse, W.D., 2009. Introduction to Mineralogy: International Edition. OUP USA; International ed edition, 466 p. 9. Williams, H., Turner, F.J., and Gilbert, C.M., 1982. Petrography, an introduction to the study of rocks in thin sections. 2nd ed. W.H. Freeman and Co., New York, 626p. 10. Yardley, B.W.D., MacKenzie, W.S. and Guilford C., 1990. Atlas of Metamorphic Rocks and Their Textures. Prentice Hall, 128 p. .

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Thin Section Petrography for Ceramic Glaze Microstructures
minerals Commentary Breaking Preconceptions: Thin Section Petrography For Ceramic Glaze Microstructures Roberta Di Febo 1,2,3,*, Lluís Casas 4 , Jordi Rius 5, Riccardo Tagliapietra 6 and Joan Carles Melgarejo 7 1 Dept. de Ciències de l’Antiguitat i Edad Mitjana, Facultat de Filosofia i Lletres, Universitat Autònoma de Barcelona (UAB), Edifici B, 08193 Bellaterra, Spain 2 Institut Català d’Arqueologia Clàssica (ICAC), Unitat d’Estudis Arqueomètrics (UEA), Plaça d’en Rovellat, s/n, 43003 Tarragona, Spain 3 U Science Tech, MECAMAT group, University of Vic—Central University of Catalonia, C. De la Laura 13, 08500 Catalonia, Spain 4 Departament de Geologia, Universitat Autònoma de Barcelona, 08193 Bellaterra, Spain; [email protected] 5 Institute de Ciència de Materials de Barcelona (ICMAB-CSIC), Campus de la UAB, 08193 Bellaterra, Spain; [email protected] 6 Renishaw S.p.A Via dei Prati 5, 10044 Pianezza (TO), Italia; [email protected] 7 Departament de Mineralogia, Petrologia i Geologia Aplicada, Facultat de Ciències de la Terra, Universitat de Barcelona, Martí i Franquès s/n, 08028 Barcelona, Spain; [email protected] * Correspondence: [email protected] or [email protected]; Tel.: +34-977-249-133 Received: 16 December 2018; Accepted: 12 February 2019; Published: 15 February 2019 Abstract: During the last thirty years, microstructural and technological studies on ceramic glazes have been essentially carried out through the use of Scanning Electron Microscopy (SEM) combined with energy dispersive X-ray analysis (EDX). On the contrary, optical microscopy (OM) has been considered of limited use in solving the very complex and fine-scale microstructures associated with ceramic glazes.
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Optical Mineralogy in a Nutshell
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Igneous Petrology 2001
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