Master Program Polymer Science Module Handbook

Transcription

1 Master Program Polymer Science Module Handbook Whiskers of a polymer additive in a melt of polypropylene July 2015

2 Content Page Introduction and Overview 3 1 st Semester (Winter Semester) P 101 Polymer Synthesis 8 P 102 Physical Chemistry of Polymers 9 P 103 Colloids and Surfaces 10 P 104 Polymer Materials and Technology 11 P 105 Polymer Physics I 12 P 106 Organometallic Chemistry and Polymerization Catalysts 13 P 107 Biomacromolecules 14 P 108 Biomaterials 15 2 nd Semester (Summer Semester) P 201 Polymer Architectures 16 P 202 High Performance and Speciality Polymers 17 P 203 Advanced Methods in the Physical Chemistry of Polymers 18 P 204 Current Topics in Colloid, Polymer, and Interface Science 19 P 205 Polymer Engineering 20 P 206 Polymer Physics II 21 P 207 Catalyst Design 23 P 210 Research Proposal 24 3 rd and 4 th Semester P 301 Advanced Laboratory I 25 P 302 Advanced Laboratory II 25 P 400 Master Thesis 26 2

3 Polymer Science (Macromolecular Science) is a prime example of a truly cross-disciplinary innovative area in Materials Science and one of the fastest growing disciplines. It builds upon the traditional subdivisions of chemistry (organic, inorganic and physical chemistry) and includes polymer chemistry, colloid science, polymer physics (theoretical and experimental), polymer engineering and soft matter science. The subject is particularly appealing to students because it deals with modern materials that are commercially important and part of our daily life. Furthermore, based on the predicted growth and innovation power, polymers are the key materials class of the 21 st century. Polymer Science also represents an area in which the students have high chances to find employment after graduation. In contrast to the permanent demand of polymer chemistry in industry, polymer science has traditionally been among the most neglected topics in both undergraduate and graduate education. Therefore the University of Bayreuth (UBT) has a strong commitment in teaching polymer science and an outstanding stimulating research environment. Since the foundation of the University of Bayreuth polymer and colloid science is one of the interdisciplinary focus areas with a continuous growth in terms of faculty members and scientific investments. Consequently, the UBT became one of the leading centers in Polymer Science in Germany and Europe with a strong international recognition. More than 20 research groups led by full professors, associate professors, and junior professors are presently involved with various aspects of polymer and colloid science including bio based polymers and biomacromolecules. The two-year Master Program Polymer Science focuses on the path from monomers via polymers to functional (polymer) materials and products, and covers therefore various disciplines including polymer chemistry, catalysis, colloid chemistry, physical chemistry, polymer physics, polymer processing and engineering, and polymer technology. The program includes fundamental aspects and latest developments of technological applications of polymeric materials. The program is research-oriented and introduces the students at an early stage to the current research topics in Polymer Science. This master program is based on faculty members and teaching staff that is very active, well recognized and with a long teaching experience in the different aspects of this area. The Master Program Polymer Science is open for students with a bachelor degree in chemistry, polymer and colloid chemistry, biochemistry, physics, materials engineering, and related bachelor studies. It should be pointed out that it is possible for students without prior knowledge in Polymer Science to enter the program and to participate in both the lecture and the laboratory courses of the first semester. The module concept of combining theoretical with experimental skills including the documentation of experiments and results has been proven to be a successful teaching approach. The master program starts yearly during the winter term. It is possible to enter the program in the summer term if sufficient precognition is 3

4 shown. Applications should be mailed to the coordinator of the Master Program Polymer Science. An overview of the offered curriculum of the master program is shown on page 5 and 6 and will be discussed in more detail in the following. In the first semester the students from different disciplines and backgrounds will be introduced into the fundamentals of Polymer Science. From a choice of eight recommended modules (Polymer Synthesis, Physical Chemistry of Polymers, Colloids and Surfaces, Polymer Materials and Technology, Polymer Physics, Organometallic Chemistry and Polymerization Catalysts, Biomacromolecules, and Biomaterials) each student has to select four topics. Each module, with the exception of Polymer Physics, includes an introductory lecture and a laboratory course to cover the experimental and practical aspects of the subject and to teach hands-on skills. After successful completion the students will have gained the basic theoretical and experimental knowledge, which is necessary to specialize and focus on their individual interests. In the second semester the students will have to select three advanced modules each comprising a lecture and a laboratory course. In order to bring the students as close as possible to current research the laboratory course will be held in one of the research groups associated with the master program. Recommended modules are Polymer Architectures, High Performance and Specialty Polymers, Advanced Methods in the Physical Chemistry of Polymers, Current Topics in Colloid, Polymer and Interface Science, Polymer Engineering, Polymer Physics II, and Catalyst Design. In addition students write and defend a research proposal of a research topic, which could be related to one of the research modules in the third semester or the master thesis in the fourth semester. In the third and fourth semester two research modules of each 15 credit points have to be chosen; this can also be in combination with an assignment abroad and/or in industry. These modules are intended to bring the students closer to independent research. The subject of a master thesis is on current research topics in polymer science. The master thesis with 30 credit points has duration of 6 months with the main workload in the fourth semester. Coordinator of the Master Program Polymer Science: Prof. Dr. Hans-Werner Schmidt Universität Bayreuth Makromolekulare Chemie I master.polymerscience@uni-bayreuth.de phone: 0049/921/

5 Further information: Master Program Polymer Science Bayreuth Graduate School of Mathematical and Natural Sciences Doctorade Polymer Science Focus area Polymer & Colloid Science at the University of Bayreuth Elite Study Program Macromolecular Science 5

6 In the master program Polymer Science at least 120 credit points (CP) have to be provided. Basic modules P 101 P 108 Choice: 4 out of 8 modules * Module P 101 Polymer Synthesis 7 CP Module P 102 Physical Chemistry of Polymers 7 CP Module P 103 Colloids and Surfaces 7 CP Module P 104 Polymer Materials and Technology 7 CP Module P 105 Module P 106 Module P 107 Module P 108 Polymer Physics I Organometallic Chemistry and Polymerization Catalysts Biomacromolecules Biomaterials 7 CP 7 CP 7 CP 7 CP * From eight suggested modules offered in the winter semester the students select four. It is possible to replace one of these modules by a module from master courses in chemistry, biological chemistry, physics or engineering science. Advanced modules P 201 P 207 Choice: 3 out of 7 modules ** Module P 201 Polymer Architectures 9 CP Module P 202 High Performance and Speciality Polymers 9 CP Module P 203 Advanced Methods in the Physical Chemistry of Polymers 9 CP Module P 204 Current Topics in Colloid, Polymer, and Interface Science 9 CP Module P 205 Module P 206 Module P 207 Polymer Engineering Polymer Physics II Catalyst Design 9 CP 9 CP 9 CP ** From seven suggested modules offered in the summer semester the students select three. It is possible to replace one of these modules by a module from master courses in chemistry, biological chemistry, physics or engineering science. Module Module P 210 Research Proposal 5 CP 6

7 Module*** Module P 301 Advanced Laboratory I 15 CP Module P 302 Advanced Laboratory II 15 CP P19 SWS S1 SWS P19 SWS S1 SWS *** These modules can be replaced by a laboratory course at a university abroad and/or an industrial internship. There is the possibility to substitute one module by selected modules of MSci program Polymer Science or corresponding courses of the MSci programs of chemistry, biochemistry, physics, or engineering. Module Module P 400 Master Thesis 900 hours 30 CP Compulsory optional modules will be offered as far as possible and demand. They will be announced in appropriate form by the chairman of the board of the coordinator of the Master Program Polymer Science at the end of the previous lecture period. 7

8 Module P 101: Polymer Synthesis The major objective of the module is to provide basic knowledge about the different polymerization methods and the theoretical background. In addition the students learn about the synthesis and structure-property relation of selected engineering plastics and high performance polymers. In the laboratory course the students learn how to carry out polymerization reactions practically on the basis of selected experiments. Module P 101 Polymer Synthesis is comprised of the following units: Lecture 2 WS Laboratory Course 6 WS This module will be offered by lecturers of Macromolecular Chemistry The lecture provides broad knowledge of the basic polymerization techniques including radical polymerization, cationic and anionic polymerization, polycondensation, and polyaddition. Special emphasis is given to modern synthetic procedures. In addition selected polymers for special applications like polyurethanes, polycarbonates, and fluoropolymers will be presented. In the laboratory course the knowledge on the different polymerization techniques is intensified in selected experiments from the fields of copolymerization, controlled radical polymerization, anionic polymerization, and polycondensation. The prepared polymers will be characterized by methods such as GPC, MALDI-TOF and viscosimetry. none A written (or oral) examination on the contents of the lecture and the laboratory course after the first semester. This amounts to 60% of the final grade. A second grade is given for the laboratory course and amounts to 40% of the final grade. The kind of examination (written or oral) and the date are given at the beginning of the semester. In addition to the 2 HPW for the lecture 1 hour is planned for individual studies. Accordingly, 3 additional hours are necessary for the preparation of the experiments and the protocol of the 6 HPW laboratory course. Given 15 weeks per semester this adds up to 180 hours. Together with 30 hours for the preparation of the final examination a total work load of 210 hours for the whole semester is calculated. ECTS Credit points: 7 8

9 Module P 102: Physical Chemistry of Polymers The course will provide knowledge about the structure of macromolecules, the thermodynamics of polymer solutions, the molecular characterization of polymers and basics of the properties of polymers in the condensed state (melt and solid state) and of their mechanical properties. Module P 102 Physical Chemistry of Polymers comprises of the following course units: Lecture 2 WS Laboratory Course 6 WS This module will be offered by lecturers of Physical Chemistry and Macromolecular Chemistry The lecture will cover: the spatial structure of single macromolecules (radius of gyration and segment density distribution of a Gaussian coil), thermodynamics of polymer solutions (Flory- Huggins theory, osmotic pressure, phase diagrams), polymer analytics (osmosis, viscosimetry, scattering methods, chromatography, mass spectrometry), macromolecules in the melt and the solid state (glass transition, crystallization), basics of mechanical properties (viscoelastic properties, rubbers, rheology). The laboratory course will provide selected experiments on polymer analytics such as chromatography, mass spectrometry, scattering methods, rheology, optical and electron microscopy. none A written (or oral) examination on contents of the lecture and the laboratory course after the first semester amounts to 60% of the final grade. A second grade is given for the laboratory course and amounts to 40% of the final grade. The kind of examination (written or oral) and the date are given at the beginning of the semester. In addition to the 2 HPW for the lecture, 1 hour is planned for individual studies. Additionally, 3 hours are necessary for the preparation of the experiments and the protocol of the 6 HPW laboratory course. Given 15 weeks per semester this adds up to 180 hours. Combined with 30 hours for the preparation of the final examination a work load of 210 hours for the whole semester is calculated. ECTS Credit points: 7 9

10 Module P 103: Colloids and Surfaces The course will provide knowledge about advanced physical chemistry of colloids i.e. phase behaviour, structure formation, and dynamics in microemulsions; properties of nanoparticles, block copolymer micelles, and formation of mesoscopic crystals. Also properties of interfaces, smart surfaces, confinement effects in thin films and wetting phenomena will be presented. Module P 103 Colloids and Surfaces is comprised of the following course units: Lecture 2 WS Laboratory Course 6 WS This module will be offered by lecturers of Physical Chemistry The lecture will cover: Phase behaviour of binary and ternary mixtures of water, oil, and amphiphiles. Amphiphiles can be surfactants, lipids, block copolymers, and colloids. The Helfrich concept of the bending elastic energy will be introduced. Moreover, mixed polymer surfactant systems will be treated. The scattering techniques which are relevant for these bulk systems will be briefly discussed (e.g. SANS). This part will be followed by a section about surfaces with an emphasis on thin polymer films and polyelectrolyte multilayers. The relevant experimental techniques will be introduced such as scanning force microscopy (AFM), scanning tunneling microscopy (STM), scanning near-field optical microscopy (SNOM) and ellipsometry. In the laboratory course the students will deal with synthesis and characterization of colloidal particles using microscopic techniques and light scattering methods. Moreover, the phase behaviour of a ternary system (surfactant/oil/water) will be investigated using small angle X-ray scattering. Finally colloids or polyelectrolytes will be assembled at surfaces and interfaces. The resulting structures are characterized using methods such as AFM and ellipsometry. none A written (or oral) examination on the contents of the lecture and the laboratory course after the first semester. This amounts to 60% of the final grade. A second grade is given for the laboratory course and amounts to 40% of the final grade. The kind of examination (written or oral) and the date are given at the beginning of the semester. In addition to the 2 HPW for the lecture 1 hour is planned for individual studies. Accordingly, 3 additional hours are necessary for the preparation of the experiments and the protocol of the 6 HPW laboratory course. Given 15 weeks per semester this adds up to 180 hours. Together with 30 hours for the preparation of the final examination a work load of 210 hours for the whole semester is calculated. ECTS Credit Points: 7 10

11 Module P 104: Polymer Materials and Technology This module will provide systematic knowledge about conventional and advanced processing technologies of polymer materials. The objective is to understand the entire process chain starting from the selection of the polymer material, the involved processing to the final component in view of the desired properties. Module P 104 Polymer Materials and Technology is comprised of the following units: Lecture 2 WS Laboratory Course 6 WS This module will be offered by lecturers of Polymer Engineering and Macromolecular Chemistry The lecture provides detailed knowledge of the basic polymer processing techniques, such as injection moulding, extrusion, secondary shaping techniques, as well as general applications. In addition basic thermal and mechanical characterization methods are reviewed. A special emphasis will be given on the relationship between processing parameters and resulting product properties. In the laboratory course the knowledge on the different processing and characterization techniques is enhanced by experiments using state-of-the-art machines and equipment. Thus processes such as injection moulding and film extrusion are performed and thermal, optical, and mechanical properties will be evaluated on the produced components. None A written (or oral) examination on contents of the lecture and the laboratory course after the first semester. This amounts to 60% of the final grade. A second grade is given for the laboratory course and amounts to 40%. The kind of examination (written or oral) and the date are given at the beginning of the semester. In addition to the 2 HPW for the lecture 1 hour is planned for individual studies. Three additional hours are necessary for the preparation of the experiments and the protocol of the 6 HPW laboratory course. Given 15 weeks per semester this adds up to 180 hours. Together with 30 hours for the preparation of the final examination a work load of 210 hours for the whole semester is calculated. ECTS Credit points: 7 11

12 Module P 105: Polymer Physics I This module will provide the understanding of fundamental concepts of polymer and soft matter physics. A central goal is the understanding of polymer effects in the light of concepts known from molecular and solid state physics and the interpretation of important experimental results within the framework of reasonably simple physical models. Module P 105 Polymer Physics I is comprised of the following units: Lecture 3 WS Exercises 1 WS This module will be offered by lecturers of Theoretical Physics and Experimental Physics The lecture will cover single chain properties, chain models, distribution functions and averages, collective properties, rubber elasticity, rheology, polymer solutions, polymer blends, phase diagrams, block copolymers, structure factor, scattering, experimental techniques, polymer characterization, theoretical models, glass transition, and gelation. None Written (or oral) examination on contents of the lecture and exercises. The kind of examination (written or oral) and the date are given at the beginning of the semester. Attending time: 60 hours; pre- and post-preparation: 60 hours; additional time of preparation for examination: 60 hours. Total work load: 180 hours. ECTS Credit points: 7 12

13 Module P 106: Organometallic Chemistry and Polymerization Catalysts The Students gain insight into polymerization catalysis and improve their knowledge in organometallic chemistry. Module P 106 Organometallic Chemistry and Polymerization Catalysts is comprised of the following course units: Lecture 2 WS Laboratory Course 6 WS This module will be offered by lectures of Organic and Inorganic Chemistry During the lecture the following topics are discussed: reactivity of the metal carbon bond, catalytic applications of organometallic compounds and coordinative polymerizations. In the laboratory course the students improve skills to work with highly air and moisture sensitive compounds and use them in teamwork with PhD students and postdocs to address catalysis relevant questions. None A written examination (if less than seven students enrol for this course an oral examination) covering the content of the lecture amounts to 60 % and the quality of the lab course to 40%. Lab. course assessment results from the quality of the catalyst syntheses and the quality of the catalytic experiments. The kind of examination (written or oral) and the date are given at the beginning of the semester. The lecture results in 60 hours work load including lecture preparation and the laboratory course work load is 120 hours. 30 hours are needed to prepare for the examination. Overall work load: 210 h. ECTS Credit Points: 7 13

14 Module P 107: Biomacromolecules This module will provide an integrated presentation of the structure and function of biomacromolecules such as nucleic acids and proteins, and it will present advanced treaties of individual classes of biomacromolecules. In addition, the physical, chemical, and mathematical description of biopolymers as well as methods of analysis of this class of molecules will be introduced. The module will build on introductory courses in biochemistry, biophysical chemistry, molecular biology, and biophysics. The students of this module will gain a basic knowledge of the field enabling them to understand research in molecular biophysics and biophysical chemistry as well as to conduct independent laboratory experiments. Module P 107 Biomacromolecules is comprised of the following course units: Lecture 2 WS Laboratory Course 5 WS/SS* This module will be offered by lecturers of Biochemistry and Biophysical Chemistry The lecture will cover the structure and function of nucleic acids, proteins, and other biomacromolecules. In addition, analytical methods to analyze biomacromolecules will be presented. Basic rules of quantum mechanics, Fourier transformation, optic and magnetic transitions as well as the description of the time dependence of molecular systems will be covered. In the laboratory course the students improve skills to apply the presented methods and procedures to the study biomacromolecules. The laboratory course includes a seminar on selected research topics in biophysical chemistry. Introductory course (passed) in at least one of the fields biochemistry, biophysical chemistry, molecular biology, biophysics, and macromolecular chemistry. Written examination (if less than seven students enrol for this course, the examination may be oral). Type of examination (oral/ written) and date will be given at the beginning of the semester. The lecture results in 60 hours work load including lecture preparation, and the laboratory course work load is 120 hours (module with 7 credits) / 180 hours (module with 9 credits). 30 hours are needed to prepare for the examination. The overall work load is: 210 hours (module 7 credits) / 270 hours (module 9 credits). ECTS Credit Points: 7 14

15 Module P 108: Biomaterials This module focuses on bio-inspired materials and processes. The students will learn about structure, synthesis, and modification of biopolymers, including biomineralization. Furthermore, the students will gain a comprehensive insight in current research topics and industrial applications. The characterization and analysis of mechanical and structural properties of biomacromolecules plays also an important role in this module. Module P 108 Biomaterial is comprised of the following courses: Lecture 2 WS Laboratory Course 6 WS This module will be offered by the chair of Biomaterials / FAN. A major objective of the lecture is the applications of nucleic acids, lipids, and proteins in nanotechnology, pharmacology, and industry. Furthermore, the course deals with the science behind the assembly of macromolecules, the biomineralisation process and their man-made imitations. Important characterization methods, such as field-flow fractionation, CD-, UV-, IR- and fluorescence spectroscopy, AFM, EM, HPLC, and mechanical testing are presented. Additionally molecular and microbiological methods and techniques are introduced. The laboratory course puts the students in a position to apply these methods for instance on spider silk, mussel collagens, and yeast proteins. none The module will be evaluated by an oral or written examination (60%) and the evaluation of the laboratory course consisting of the practical performance and a report (40%). In addition to 2 hours of lecture, 2 more hours are necessary for the preparation and the review of the lecture. This will add up to 60 hours for the entire semester. The laboratory course accounts for 120 hours. Furthermore, preparations for the examination are estimated to additional 30 hours. This adds to a sum of 210 hours. ECTS Credit points: 7 15

16 Module P 201: Polymer Architectures This module will enable the student to design polymers with well-defined structures, based on living/controlled polymerization techniques. The students will learn the solution and bulk properties of polymers with selected architectures. Module P 201 Polymer Architectures is comprised of the following course units: Lecture 2 SS Laboratory Course 8 SS This module will be offered by lecturers of Macromolecular Chemistry The lecture consists of two parts. In the first part the mechanisms of living/controlled polymerizations (anionic, cationic, radical, coordinative, ring-opening) will be discussed in great detail. The second part will cover Macromolecular Engineering, i.e. the synthesis and properties of various polymer architectures will be discussed in detail, e.g. block and graft copolymers, star-branched and hyperbranched polymers, organic and hybrid nanoparticles. The associated laboratory course will be performed in one of the macromolecular chemistry research groups in collaboration with PhD students and post-docs. It will cover the synthesis and characterization of given polymer structures. Participation in P101 (Polymer Synthesis) and P102 (Physical Chemistry of Polymers) is recommended. An oral (or written) examination on the contents of the lecture after the second semester. This examination will amount to 50 % of the grade. The laboratory course will be evaluated by the average of three independent grades: Practical performance, written report, and a seminar and amount to 50 % of the grade. In addition to the 2 HPW for the lecture 2 hours are planned for individual studies. Accordingly, 4 additional hours are necessary for the preparation of the experiments and the protocol of the 8 HPW laboratory course. Given 15 weeks per semester this adds up to 240 hours. Together with 30 hours for the preparation of the final examination a work load of 270 hours for the whole semester is calculated. ECTS Credit Points: 9 16

17 Module P 202: High Performance and Specialty Polymers During the last decades organics and polymers have successfully entered and opened new application fields and replaced other materials. In this module the students will learn about the design, synthesis, and structure-property relation of high performance and specialty polymers. Since a number of research groups at the University of Bayreuth are active in this research area the students will be introduced to cutting edge science in this field. Module P 202 High Performance and Specialty Polymers is comprised of the following course units: Lecture 2 SS Laboratory Course 8 SS This module will be offered by lecturers of Macromolecular Chemistry In the lecture the design, synthesis, and structure-property relation of organic functional materials and specialty polymers will be discussed with respect to advanced applications such as optics, information storage, solar cells, organic electronics, photolithography, and display technology. The associated laboratory course will be done in one of the macromolecular chemistry research groups working on high performance organic materials and specialty polymers. The students will be introduced into the synthesis of new materials as well as their detailed physical characterization and their application in devices. None An oral (or written) examination on the contents of the lecture after the second semester. This examination will amount to 50 % of the grade. The laboratory course will be evaluated by the average of three independent grades: Practical performance, written report, and a seminar and amount to 50 % of the grade. In addition to the 2 HPW for the lecture 2 hours are planned for individual studies. Accordingly, 4 additional hours are necessary for the preparation of the experiments and the protocol of the 8 HPW laboratory course. Given 15 weeks per semester this adds up to 240 hours. Together with 30 hours for the preparation of the final examination a work load of 270 hours for the whole semester is calculated. ECTS Credit Points: 9 17

18 Module P 203: Advanced Methods in the Physical Chemistry of Polymers The students will be introduced to theoretical and practical knowledge of advanced microscopic tools. Module P 203 Advanced Methods in the Physical Chemistry of Polymers is comprised of the following course units: Lecture 2 SS Laboratory Course 8 SS This module will be offered by lecturers of Physical Chemistry The lecture will present new complex experimental techniques, which can be used in the study of soft matter such as Cryo-transmission electron microscopy, scanning electron microscopy, AFM-force spectroscopy, surface force apparatus (SFA), total internal reflection microscopy (TIRM), fluorescence microscopy techniques (e.g. fluorescence correlation spectroscopy), scattering methods (e.g. neutron spin echo techniques (NSE), grazing incidence small angle x-ray scattering (GISAXS)) and x-ray photon correlation spectroscopy (X-PCS). The associated laboratory course will be done in the physical chemistry research groups and will introduce to the use of advanced scattering and microscopy equipment. Participation in P102 (Physical Chemistry of Polymers) is recommended. An oral (or written) examination on the contents of the lecture after the second semester. This examination will amount to 50 % of the grade. The laboratory course will be evaluated by the average of three independent grades: Practical performance, written report, and a seminar and amount to 50 % of the grade. In addition to the 2 HPW for the lecture 2 hours are planned for individual studies. Accordingly, 4 additional hours are necessary for the preparation of the experiments and the protocol of the 8 HPW laboratory course. Given 15 weeks per semester this adds up to 240 hours. Together with 30 hours for the preparation of the final examination a work load of 270 hours for the whole semester is calculated. ECTS Credit Points: 9 18

19 Module P 204: Current Topics in Colloid, Polymer, and Interface Science The aim of the course is to present current research areas in the field of the physical chemistry of polymers, colloids, and interfaces. Module P 204 Current Topics in Colloid, Polymer, and Interface Science is comprised of the following course units: Lecture 2 SS Laboratory Course 8 SS This module will be offered by lecturers of Physical Chemistry Topics currently treated in the physical chemistry research groups will be presented in four different blocks. The blocks will contain the respective fundamentals and recent results on the discussed subject. The respective laboratory course can be chosen from the four presented subjects and will be carried out in the PC research groups. Participation in P103 (Colloids and Surfaces) is recommended. An oral (or written) examination on the contents of the lecture after the second semester. This examination will amount to 50 % of the grade. The laboratory course will be evaluated by the average of three independent grades: Practical performance, written report, and a seminar and amount to 50 % of the grade. In addition to the 2 HPW for the lecture 2 hours are planned for individual studies. Accordingly, 4 additional hours are necessary for the preparation of the experiments and the protocol of the 8 HPW laboratory course. Given 15 weeks per semester this adds up to 240 hours. Together with 30 hours for the preparation of the final examination a work load of 270 hours for the whole semester is calculated. ECTS Credit Points: 9 19

20 Module P 205: Polymer Engineering The objective of this module is to provide detailed knowledge about the processing and properties of reinforced polymer materials. The lecture will cover various concepts to reinforce polymeric matrices. The students will also obtain an overview about relevant technical applications of these advanced engineering polymers. In addition the laboratory course will expend their knowledge in polymer engineering. Module P 205 Polymer Engineering is comprised of the following units: Lecture 2 SS Laboratory Course 8 SS This module will be offered by lecturers of Polymer Engineering. The lecture will provide detailed knowledge in processing and characterization of reinforced polymers with industrial importance. Various reinforcement mechanism, their fabrication and properties will be taught. Also modern material characterization techniques are discussed with emphasis on fracture mechanics and long-term dynamic response of composites. The associated laboratory course will be performed in the polymer engineering research group or in collaboration with other polymer engineering related groups. For all students module P 104 is mandatory. An oral (or written) examination on the contents of the lecture after the second semester. This examination will amount to 50 % of the grade. The laboratory course will be evaluated by the average of three independent grades: Practical performance, written report, and a seminar amounting to 50 % of the grade. In addition to the 2 HPW for the lecture 2 hours are planned for individual studies. Four additional hours are necessary for the preparation of the experiments and the protocol of the 8 HPW laboratory course. Given 15 weeks per semester this adds up to 240 hours. Together with 30 hours for the preparation of the final examination and talk a work load of 270 hours for the whole semester is calculated. ECTS Credit points: 9 20

21 Module P 206: Polymer Physics II Introduction to advanced topics in polymer and soft matter physics Module P 206 Polymer Physics II is comprised of the following units: Lecture I + Exercises 4 SS Lecture II + Exercises 4 SS This module will be offered by lecturers of Theoretical Physics and Experimental Physics Course contents: The module consists of 1. one lecture (incl. exercises) with 6 ECTS credit points from the following list: Organic semiconductors Electronic structure, charged excitations, neutral excitations, charge transport models, energy transfer models, interfacial dynamics, devices, experimental and theoretical methods Physics of the amorphous state Structure of glasses, atomic dynamics, glass transition, stochastic models, polymer specific dynamics, computer simulations, theory of the glass transition Non-equilibrium thermodynamics and statistics Systems far from equilibrium, correlation functions and linear response, stochastic processes, Langevin-dynamics, nonlinear dynamics and self organization, generalized potentials, examples Nuclear magnetic resonance and polymers Bloch equations, free induction decay and spectrum, diffusion, tomography, field cycling, quantum mechanical treatment, density matrix formalism, local field, coupling, advanced methods 2. one course with 3 ECTS credit points from the following list: Foundations of optical spectroscopy basic principles of optical spectroscopy, selected spectroscopic techniques, microscopy, energy tranfer (FRET) Practical laboratory course Three experiments from the advanced laboratory course of the master program in physics (e.g. photon correlation spectroscopy, organic light emitting diodes, nanorheology) One additional lecture from the list under item 1 21

22 Module P105 Polymer Physics I An oral (or written) examination on the contents of each lecture or of lecture I and of the practical laboratory course. Lecture I amounts to 2/3 and lecture II or the practical laboratory course amount to 1/3 of the grade. Attending time: 90 hours; pre- and post-preparation: 90 hours; additional time of preparation for examination: 90 hours. Total work load: 270 hours. ECTS Credit points: 9 22

23 Module P 207: Catalyst Design The students gain insight into the field of catalyst design. Module P 207 Catalyst Design is comprised of the following course units: Lecture 2 SS Laboratory Course 8 SS This module will be offered by lectures of Organic and Inorganic Chemistry During the lecture the following topics are discussed: basics and concepts of catalyst design: explorative coordination chemistry, mechanistic studies and combinatorial catalysis research. In the laboratory course the students develop skills to run catalytic experiments and use them in teamwork with PhD students and post-docs to address open, catalysis relevant, questions. None A written examination (if less than seven students enrol for this course an oral examination) covering the content of the lecture amounts to 50 % and the quality of the lab course to 50 %. Lab. course assessment results from the quality of the catalyst syntheses and the quality of the catalytic experiments. The lecture results in 60 hours work load including lecture preparation and the lab course work load is 180 hours. 30 hours are needed to prepare for the examination. Overall work load: 270 h. ECTS Credit Points: 9 23

24 Module 210: Research Proposal This module is aimed at acquiring basic knowledge in planning and drafting a scientific project proposal based on the existing knowledge in a specific research area. Here the students learn to prepare a sound proposal both written and oral, which helps them in planning their master thesis. Module P 210 Research Proposal is comprised of the following course units: Writing a research proposal 5 WS/SS Seminar on research topic 1 WS/SS This module will be offered by all lecturers of the Master Program Polymer Science Before starting the master thesis, the students work on a research proposal by selecting a research topic, formulating the state of the art in the literature, identifying the main objectives of the research plan, and explaining the work plan and targets based on proposed experiments. Additionally, the written research plan will be presented in a seminar in order to improve the capabilities of presentation techniques and scientific discussion. In this way the students gain experience to work more independently on research topics and to formulate well-focused research proposals. None. Written research plan (2/3 of the total grade) and oral presentation and discussion (1/3 of the total grade). For the written research plan which covers work on literature research a total of 120 hours are envisaged, whereas the seminar on the research proposal including preparation of seminar and oral presentation results in 30 hours, total work load being 150 hours. ECTS Credit Points: 5 24

25 Module P 301 and 302: Advanced Laboratory Module I and II The objective of this module is to further enhance the laboratory and science skills of the students in selected advanced fields of polymer science. The students will be introduced to current research topics investigated in one of the polymer science research groups at the University of Bayreuth. In addition the students will improve their ability to work in a team and their skills to present their research. Module P 301 and 302 Advanced Laboratory Module I and II is comprised of: Polymer science research project Group seminar presentation HPW 19 1 Semester WS/SS WS/SS This module will be offered by all professors of the Master Program Polymer Science The course covers a selected topic of current research within one of the research groups involved in the Master Program Polymer Science. The module includes experiments in the lab, literature search, participation at group seminars, and the presentation of the research results in form of a report and a seminar with discussion. The successful completion of a basic module related to the topic of the Advanced Laboratory Module is highly recommended. The laboratory experiments will be evaluated by the average of three independent grades: Practical performance, written report, and seminar. If a grade is given for a laboratory course at an foreign university the grade is based on the statement of the supervisor of the host university. An industrial internship does not involve a grade. A statement of a successful participation will be needed. 350 hours are projected for the laboratory experiments, 100 hours for the literature search, the report, and the seminar. This adds up to a total of 450 hours. ECTS Credit points: 15 25

26 Module 400: Master Thesis The students work independently on a research project under the guidance of a faculty member and write the results and discussion in the form of a thesis. Module P 400 Master Thesis comprises the following: Research project and written thesis Hours Semester 900 WS/SS This module will be offered by all lecturers of the Master Program Polymer Science The topic of the master thesis is based on a current research activity of the selected research group. A successful completion of 45 ECTS and the Module P 210 Research Proposal (5 ECTS) is required. The master thesis written and submitted at the end of the research work will be evaluated by two reviewers independently. Master thesis covers work on literature research, experimental work and the formulation of all results and discussion amounting to a total work load of 900 hours. ECTS Credit Points: 30 26

27 27 Master Program Polymer Science

28 28 Master Program Polymer Science