Presentation of the basic analytic theories important for the study celestial motions. Necessary tool for research in theoretical Celestial Mechanics. Institute of Astronomy, Geophysics and Atmospheric Sciences (IAG) São Paulo main campus Canonical equations. Canonical transformations. Separable systems. Delaunay variables. The method of Von Zeipel. Lie series transformations. Hori-Deprit method. Extended phase space. Sylvio Ferraz de Mello 30 AGA5720 11 The discipline will have the participation of Prof. Ricardo Riguera. Full Professor of the Universidade de Santiago de Compostela. Prof. RIguera has experience in the area of chemistry of polymers. http://www.iag.usp.br/international/

The course aims to give an overview about the physical principles involved in several biological phenomena on topics of biology and health sciences. Some previous experience related to applied physics in medicine and biology is expected from the students in order to provide a more advanced approach. This course gives a comprehensive overview and training on the application of physics to the understanding of biological systems. Physics concepts, statistics, electricity, magnetism, signal processing, therapy and imaging techniques, among others, are used in the discussion of issues of interest to the medical and biological physics. Faculty of Philosophy, Sciences and Letters at Ribeirão Preto (FFCLRP) Ribeirão Preto campus 1. Statistics in Medicine and Biology 2. Systems of Many Particles 3. Transport in an Infinite Medium 4. Transport Through Neutral Membranes 5. Impulses in Nerve and Muscle Cells 6. Electrical and magnetic measurements in biological systems 7. Biomedical signal processing 8. Medical use of ionizing radiation: Imaging and Therapy 9. Medical use of non-ionizing radiation: Imaging Oswaldo Baffa Filho, Ubiraci Pereira da Costa Neves, Carlos Ernesto Garrido Salmon 25 5915702 8 Evaluation Criteria: FS=0.35•E1+0.35•E2+0.30•EW FS=Final score E1 = First Written Exam E2 = Second Written Exam EW = Extra works (Seminars, Exercises) https://www.google.com.br/url?sa=t&rct=j&q=&esrc=s&source=web&cd=1&ved=0ahUKEwiBp_-p9NzYAhWHkZAKHY_oACkQFggnMAA&url=http%3A%2F%2Fwww.ffclrp.usp.br%2Fdown.php%3Fid%3D1430%26d&usg=AOvVaw3-C7BSHGAhorxoB-Rfx8dD

This course is essential for those who intend to work in many body systems, in order to describe observable macroscopic quantities from the microscopic description of the system. To introduce the basis of statistical mechanics, with a view to their application in different areas, such as magnetism, biology, nuclear physics, etc. Faculty of Philosophy, Sciences and Letters at Ribeirão Preto (FFCLRP) Ribeirão Preto campus 1. Review of ensemble theory (a) microcanonical ensemble (b) canonical ensemble (c) gran canonical ensemble and (d) pressure ensemble 2. Ideal Gas (a) classica gas: Maxwell-Boltzmann statistics (b) quantum gases: quantum statistics: Base-Einstein and Fermi-Dirac 3. Phase transitions and critical phenomena (a) simple fluids: van der Waals equation (b) simple ferromagnet: Curie-Weiss equation (c) Landau theory 4. Ising Model (a) exact solution in one dimension (b) mean-field approach 5. theory of scale and group renormalization (a) scale theory of thermodynamic potentials (b) scale of critical correlations (c) Kadanoff construction (d) Renormalization of the Ising model (e) general scheme of renormalization group Alexandre Souto Martinez 25 5915736 6 Arithmetical mean of two tests. https://www.google.com.br/url?sa=t&rct=j&q=&esrc=s&source=web&cd=1&ved=0ahUKEwiBp_-p9NzYAhWHkZAKHY_oACkQFggnMAA&url=http%3A%2F%2Fwww.ffclrp.usp.br%2Fdown.php%3Fid%3D1430%26d&usg=AOvVaw3-C7BSHGAhorxoB-Rfx8dD

This course is a continuation of semiconductor material engineering and electronic device courses. In this course, students will be exposed to the basic theories of hetero-structures and their applications for electronic and opto-electronic devices including memories. Specifically, students are exposed to the major types of GaAs and GaN-alloyed semiconductors, their physical properties and structures which make them suitable for electronic and opto-electronic devices. Heterojunction bipolar transistors and modulation-doped field effect transistors will be used to describe the basic characteristics needed for electronic device operation. Then, to explain the required characteristics for opto-electronic devices, semiconductor lasers will be used as an example. 1. Able to explain the fundamentals of semiconductor heterostructures. 2. Able to explain the fundamentals of semiconductor devices (HBT, MODFET, semiconductor laser ) including their electronic and opto-electronic characteristics. 3. Communicate and work in a team to accomplish the given assignments in writing. Malaysia-Japan International Institute of Technology UTMKL Lecture and Discussion, Co-operative and Collaborative Method, Problem Based Method. week 1 – 3, week 4 – 6, etc. AP Ir. Dr. Abdul Manaf Hashim conditional SMJE 4533 3 * Group 5 Textbook: 1. Semiconductor Physics and Devices, basic Principles: Donald A. Neamen, Third Edition, McGraw Hill. 2. Advanced Semiconductor Memories: Architectures, Designs and Applications, Ashok K.Sharma, Wiley-IEEE Press. References: 1. Solid State Electronics Devices: Ben G. Streetman, Prentice Hall (2000). 2. Semiconductor Fundamentals: Pierret R.F, Addison Wesley (1996) 3. The Essence of Solid State Electronics, Linda Edward-Shea, Prentice Hall (1996). Test, Assignment/Quizzes/Presentation, Final Examination AP Ir. Dr. Abdul Manaf Hashim mailto:abdmanaf@utm.my

The purpose of this course is to give familiar with the concepts and terminology in welding engineering. Student will understand how welding design is built on a foundation of heat flow stress, structural analysis and fitness for services. In this course the students will learn the basic theory of various materials joining processes including arc, resistance, solid state, and high energy density welding. 1. Point out the basic terminology of welding engineering. 2. Design the size of influence area by welding and estimate stresses in that area. 3. Study and explain design concepts, failure criteria and inspection method in welding engineering appeared in latest literature. Malaysia-Japan International Institute of Technology UTMKL Lecture and Discussion, Co-operative and Collaborative Method, Problem Based Method. week 1, week 2, etc. * not provided conditional SMJP 4293 3 * elective 1. Athouse, Andrew Daniel; Turnquist, C. H, Modern welding, Goodheart-Willcox Publisher, 2004. 2. Raymond Sacks, Edward Bohmart, Welding: Principles and Practices, Career Edication, 2007. 3. Larry Jeffus, welding Principles and Applications, Delmar Cengage Learning, 2007. 4. William A. Bowditch, Kevin E. Bowditch, Mark A. Bowditch, Welding Technology Fundamentals, Goodheart-Wilcox Co., 2009. Assignment, Report, Test, Final Examination * not provided

This course surveys techniquesto fabricate and analyse submicron and nanometre structures, with applications. Optical and electron microscopy is rel’iewed. Additional topics that are covered include: surface characterization,’ireparation, and measurement techniques, resist technology, optical projection, interferometric, X-ray, ion, and electron lithography; Aqueous, ion, and plasma etching techniques; lift-off and electroplating; and ion implantation. Applications in microelectrinics,-microphotonics, information storage, and nanotechnology will also be explored.
1. Point out resolution limits for lithographic and imaging/inspection tools. 2. Organize nanometre and micro meter role in both microscopy, lithography and the impact factors tbr microscopy. 3. Explain articles on nanolithography and microscopy from the recent Iiterature. 4. Prepare the report based on case study of current issue in nanometre and micrometre technology.
Malaysia-Japan International Institute of Technology UTMKL Lecture and Discussion, Co-operative and Collaborative Method, Problem Based Method. week 1, week 2, etc. Dr. Hafizal Yahaya conditional SMJP 4243 3 * elective 1. Heinrich, A. J., C. P. Lutz, J. A. Gupt4 and D. M. Eigler. “Molecule Cascades.” Science 298 (2002):1381-7. 2. Goodberlet, James G. “Patterning Sub-50 nm Features with Near-field Embedded-amplitude Masks.” Applied Physics Letters 81, no. 7 (August 2002). 3. Buck, D. A., and K. R. Shoulders. “An Approach to Microminiature Printed Systems.” Eastern Joint Computer Conference (July 1959): 55-59.
Assignment, Test, Presentation. Dr. Hafizal Yahaya mailto:hafizal.kl@utm.my

The course “Tribology” provides a basic knowledge on contact, friction, wear and lubrication. Besides the basic knowledge described above, this course would provide the example of practical application of tribology. 1. Differentiate and explain technical terms in tribology field. 2. Analyze and explain the functions of tribological phenomena appeared in industrial products. 3. Select the suitable model of the simple contact, sliding or rolling contact phenomena using fundamental tribology knowledge. 4. Combine the fundamental scientific knowledge and the problems in the modern tools which is necessary in tribology field. Malaysia-Japan International Institute of Technology UTMKL Lecture, Tutorial and Discussion, Individual and Group Assignment, Written Test. week 1, week 2, etc. Prof. Dr. Kanao Fukuda conditional SMJP 3063 3 * elective 1. Bowden, F.P. and Tabor, D., “The Friction and lubrication of Solids, ” Oxford University Press, 1986. 2. E. Rabinowicz, Friction and Wear of Materials, John Wiley and Sons, 1965. 3. Gwidon Stachowick and Andrew W. Bachelor, Engineering Tribology, Third edition, John Wiley, 2005. Quiz, Assignment, Final Examination Prof. Dr. Kanao Fukuda mailto:Fukuda.kl@utm.my

This course is to familiarize the students with the sources of vibration and noise and expose the students to the fundamental of mechanical vibrations and noise engineering. It provides the students with the tools essential to tackle the problem of vibrations produced in machines and structures due to unbalance forces, vibrations isolation, two degree of freedom system, multi-degree of freedom system and continuous system. A noise part is devoted to sound level and subjective response to sound, noise, effects, ratings and regulations and Noise: sources, isolation and control. 1. Define the concepts of vibration and noise 2. Analyse and formulate the system from single degree to multi degree of freedom systems and practice case studies on the field of vibration and noise. 3. Present the sources of noise and vibrations and presents clearly the methods to control it. Malaysia-Japan International Institute of Technology UTMKL Lecture, Problem Based Learning, Co-operative Learning and Presentation. week 1 – 2, week 3 – 4, etc. AP Dr. Aminudin Abu conditional SMJP 3263 3 * elective 1. Thomson, W. T., Theory of Vibration and Its Applications, prentice Hall, New Delhi, 1982. 2. A. G. Ambekar, Mechanical Vibrations and Noise Engineering, PHI Learning Private Ltd. New Delhi, 2013. 3. Rao, J. S and Gupta, K., Introductory course on theory and practice of mechanical vibrations, Wile Eastern, New Delhi, 1984. Test, Assignment, Project, Final Examination AP Dr. Aminudin Abu mailto:aminudin.kl@utm.my

This introductory course aims to provide an overview of solid and hazardous waste management, whereby the student will be able to have the basic understanding of waste management upon their completion of the course.
The course deals with sources, generation and characteristics of industrial and municipal wastes, analysis of collection systems, handling and disposal practices of municipal wastes, significance of industrial wastes as environmental pollutants, pollution prevention and techniques for processing, treatment and disposal of industrial wastes 1. Identify sources and characteristics of industrial and municipal solid waste. 2. Describe national and international policy and legislation that related to waste management Identify and design suitable systems for collection, transportation and haulage of solid waste 3. Identify and design suitable systems for collection, transportation and haulage of solid waste 4. Manage Scheduled Waste according to the requirement set by the local regulatory body under the Scheduled Waste 5. Regulation Design material recovery facility, composting plants, thermal treatment system and landfill Seek in literature about the sources, generation and characteristics of industrial and municipal wastes, analysis of collection systems, handling and disposal practices of municipal wastes, significance of industrial wastes as environmental pollutants, pollution prevention and techniques for processing, treatment and disposal of industrial wastes

Malaysia-Japan International Institute of Technology UTMKL Lecture and Discussion, Assignment, Group Project, Presentation. week 1, week 2, etc. * not provided conditional SMJC 4533 3 * Group 2 1. Tchobanoglous, G., Theisen, H., and Eliassen, R., 1997, Solid Wastes: Engineering principles and management issues, McGraw Hill, New York. Quiz, Assignment, Test, Final Examination * not provided

This course provides the fundamentals of polymer science and engineering with emphasis on polymeric materials and their classifications, molecular weight, polymers in solution and solid state, thermal properties and the relationship as well as the implication on polymer synthesis. 1. Describe basic properties and classification of polymers, calculate average molecular weight of the polymer and the implications from the molecular weight differences with respect to properties and processing. 2. Compare and contrast between step-growth polymerization and addition polymerization techniques and determine simple chemical reaction kinetic. 3. Explain the concept of solubility, factors affecting solubility and determine the solubility parameter based on the molecular structure of the polymer. 4. Distinguish between crystalline and amorphous region in polymers and describe thermal behaviour of polymers and factors affecting the thermal transition and properties in polymeric material. 5. Identify and explain general processing techniques used to process polymeric material. Malaysia-Japan International Institute of Technology UTMKL Lecture and Discussion. week 1 – 2, week 3 – 5, etc. Prof. Dr. Mikio Miyake conditional SMJC 4423 3 * Group 1 1. Joel R. Fried, “Polymer Science & Technology”, Prentice Hall International , New Jersey, 1996. Quiz, Assignment, Test, Final Examination Prof. Dr. Mikio Miyake
Dr. Roshafima Rasit Ali
Dr. Kamyar Syameli mailto:miyake@utm.my,roshafima@utm.my,kamyar@utm.my

The students will be introduced to the basic principles and application of heat and mass transfer engineering. The understanding from this course will lead to better understanding in distillation, absorption, liquid-liquid extraction, membrane separation, leaching, evaporation and other chemical processes. 1. Explain the equation, which relate to heat and mass transfer system for steady state and unsteady state conditions. 2. Calculate the rate of transfer (mass or heat) using empirical equations for every system. Malaysia-Japan International Institute of Technology UTMKL Lecture and Discussion, Cooperative Learning, Group Projects week 1, week 2 – 3, etc. AP Dr. Kenichi Yoneda conditional SMJC 2253 3 Sem 4 1. Geankoplis, C.J., 2003. Transport Processes and Separation Processes Principles, 4th Ed., Prentice Hall. 2. McCabe, W. L., Smith J.C. and Harriot, P., 1993. Unit Operation of Chemical engineering, 5th Ed., McGraw-Hill International, Assignment, Test, Final Examination AP Dr. Kenichi Yoneda mailto:kenichi@utm.my

Students will be introduce with several types of unit operations and separation processes such as particle technology, crystallization, solid-liquid separation, filtration, membrane separation processes, drying and evaporation in this subject. Examples and exercises from related industry will be used in this subject. 1. Describe the different of solid-liquid operations process and equipment. 2. Solve complex engineering problem related to mechanical separation, size reduction process and crystallization process. 3. Apply knowledge of solid handling for chemical engineering design. Work in a group as a leader or member to conduct related activities. 4. Acquire additional knowledge from industry to comply the knowledge of solid-liquid separation process for life-long learning. Malaysia-Japan International Institute of Technology UTMKL Lecture and Discussion, Active Learning, Independent Study, Group Project. Prof.Dr.Ezzat Chan bin Abdullah conditional SMJC 3283 3 Sem 6 1. Geankoplis, C.J., 2003. Transport Processes and Separation Processes Principles (includes Unit Operation), 4th Ed., Prentice Hall, ISBN-13:978-0131013674. 2. Seader, J.D., Henley, E.J. and Roper, D.K., 2010. Separation Process Principles, 3rd Ed. Wiley, ISBN-13: 9780470481837. 3. McCabe, W. L., Smith J.C. and Harriot, P., 2004, Unit Operation of Chemical Engineering, 7th Ed., McGraw-Hill International, ISBN-13:978-0072848236. Wankat, P.C., 2012, Separation Process Engineering, includes Mass Transfer Analysis, 3rd Edition. Pearson, ISBN-13: 978-0132790215 Assignment, Test, Project, Final Examination Prof.Dr.Ezzat Chan bin Abdullah
Dr. Mariam Firdhausbinti Mad Nordin mailto:ezzatc@utm.my,mariamfirdhaus@utm.my