Suchergebnis: Katalogdaten im Herbstsemester 2019
Chemie Master  | ||||||
 Master-Studium (Studienreglement 2018) | ||||||
| Kernfächer | ||||||
| Anorganische Chemie Angebot im Frühjahrssemester | ||||||
| Organische Chemie | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
|---|---|---|---|---|---|---|
| 529-0233-01L | Organic Synthesis: Methods and Strategies IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W+ | 6 KP | 3G | E. M. Carreira | |
| Kurzbeschreibung | The complex relation between structural analysis, methods leading to desired transformations, and insight into reaction mechanisms is exemplified. Relations between retrosynthetic analysis of target structures, synthetic methods and their combination in a synthetic strategy. | |||||
| Lernziel | Extension and deepening of the knowledge in organic synthesis and the principles of structure and reactivity. | |||||
| Inhalt | Begriffe der Planung (Strategie und Taktik) der organischen Synthese, Retrosynthetische Analyse, Vertiefung der Beziehungen zwischen Struktur und Reaktivität im Zusammenhang mit der Synthese organischer Verbindungen zunehmender Komplexität. Vertiefung und Ergänzung der Kenntnisse synthetischer Methoden. | |||||
| Literatur | K. C. Nicolaou, E. J. Sorensen, Classics in Total Synthesis, Wiley-VCH 1996. K. C. Nicolaou, S. A. Snyder, Classics in Total Synthesis II, Wiley-VCH 2003. K. C. Nicolaou, J. Chen, Classics in Total Synthesis III, Wiley-VCH 2011. | |||||
| Voraussetzungen / Besonderes | OC I-IV | |||||
| 529-0241-10L | Advanced Methods and Strategies in Synthesis IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure you register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W+ | 6 KP | 3G | J. W. Bode | |
| Kurzbeschreibung | Advanced Modern Methods and Strategies in Synthesis | |||||
| Lernziel | Kenntnis der modernen Methoden der asymmetrischen Synthese, der enantioselektiven Katalyse, und organische Reactionsmechanismus. | |||||
| Inhalt | Aktuelle Trends in Methoden für und Annäherungen an die Synthese von komplexen Naturstoffen, Pharmazeutika und biologischen Molekülen, Fragmentkopplungs- und Schutzgruppenstrategien; chemische Ligation und Biomolekülsynthese; enantioselektive Katalyse einschließlich Ligandendesign und -optimierung; Kreuzkupplungsreaktionen voraktivierter Vorstufen; C-H-Aktivierung und Oxidationen; Bausteinsynthese mit chiralen Auxilliaren und Reagenzien; neue Konzepte in der asymmetrischen Katalyse. Analyse von Schlüsselliteratur inklusive der Erkennung von Trends, bedeutenden Präzedenzfällen und neu aufkommenden Gebieten wird hervorgehoben. | |||||
| Skript | will be provided in class and online | |||||
| Literatur | Suggesting Textbooks 1. Walsh and Kozlowski, Fundamentals of Asymmetric Catalysis, 1st Ed., University Science Books, 2009. 2. Anslyn and Dougherty, Modern Physical Organic Chemistry, 1st Ed., University Science Books, 2006. | |||||
| Physikalische Chemie | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0433-01L | Advanced Physical Chemistry: Statistical Thermodynamics IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W+ | 6 KP | 3G | G. Jeschke, J. Richardson | |
| Kurzbeschreibung | Introduction to statistical mechanics and thermodynamics. Prediction of thermodynamic and kinetic properties from molecular data. | |||||
| Lernziel | Introduction to statistical mechanics and thermodynamics. Prediction of thermodynamic and kinetic properties from molecular data. | |||||
| Inhalt | Basics of statistical mechanics and thermodynamics of classical and quantum systems. Concept of ensembles, microcanonical and canonical ensembles, ergodic theorem. Molecular and canonical partition functions and their connection with classical thermodynamics. Quantum statistics. Translational, rotational, vibrational, electronic and nuclear spin partition functions of gases. Determination of the equilibrium constants of gas phase reactions. Description of ideal gases and ideal crystals. Lattice models, mixing entropy of polymers, and entropic elasticity. | |||||
| Skript | See homepage of the lecture. | |||||
| Literatur | See homepage of the lecture. | |||||
| Voraussetzungen / Besonderes | Chemical Thermodynamics, Reaction Kinetics, Molecular Quantum Mechanics and Spectroscopy; Mathematical Foundations (Analysis, Combinatorial Relations, Integral and Differential Calculus) | |||||
| Projektarbeit | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0200-10L | Research Project I | W | 13 KP | 16A | Betreuer/innen | |
| Kurzbeschreibung | In a research project students extend their knowledge in a particular field, get acquainted with the scientific way of working, and learn to work on an actual research topic. Research projects are carried out in a core or optional subject area as chosen by the student. | |||||
| Lernziel | Students are accustomed to scientific work and they get to know one specific research field. | |||||
| 529-0201-10L | Research Project II | W | 13 KP | 16A | Betreuer/innen | |
| Kurzbeschreibung | In a research project students extend their knowledge in a particular field, get acquainted with the scientific way of working, and learn to work on an actual research topic. Research projects are carried out in a core or optional subject area as chosen by the student. | |||||
| Lernziel | Students are accustomed to scientific work and they get to know one specific research field. | |||||
| Industriepraktikum oder Praktikum | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0202-00L | Industry Internship Nur für Chemie MSc, Studienreglement 2018. | W | 13 KP | Betreuer/innen | ||
| Kurzbeschreibung | Mind. 7-wöchiges Praktikum in der Industrie | |||||
| Lernziel | Es ist das Ziel der 7-wöchigen Praxis, Master-Studierenden die industriellen Arbeitsumgebungen näher zu bringen. Während dieser Zeit bietet sich ihnen die Gelegenheit, in aktuelle Projekte der Gastinstitution involviert zu werden. | |||||
| 529-0739-10L | Biological Chemistry A: Technologies for Directed Evolution of Enzymes  Advanced laboratory course or internship depending on lab course Biological Chemistry B Candidates must inquire with P. Kast no later than September 1st whether course will take place (no self-enrollment) Further information to registration and work hours: www.kast.ethz.ch/teaching.html | W | 13 KP | 16P | P. A. Kast, D. Hilvert | |
| Kurzbeschreibung | Während dieses Semesterkurses werden Methoden gelehrt zur Durchführung von biologisch-chemischen Enzym-Evolutionsexperimenten mittels molekulargenetischen Mutationstechnologien und in vivo Selektion in rekombinanten Bakterienstämmen. | |||||
| Lernziel | Alle für die Experimente notwendigen Technologien werden den Studenten praxisnah vermittelt mit dem Ziel, dass sie diese im Rahmen des Praktikumsprojektes und darüber hinaus selbstständig anwenden können. Nach dem Kurs soll ein individueller Bericht über die erzielten Resultate eingereicht werden. | |||||
| Inhalt | Im Kurs werden Experimente für ein spezifisch entworfenes, echtes Forschungsprojekt durchgeführt. Dieses beinhaltet biologisch-chemische Enzym-Evolutionsexperimente mitttels molekulargenetischer Mutationsmethoden und in vivo Selektion in rekombinanten Bakterienstämmen. Im Zentrum des Kurses steht die Vermittlung von relevanten Technologien, wie die Herstellung von kompetenten Zellen, die Produktion und Isolation von DNA-Fragmenten, die Transformation von Genbanken in Bakterien und die DNA-Sequenzanalyse. Die Kursteilnehmer sollen eine Vielfalt an unterschiedlichen Varianten einer Chorismat-Mutase generieren. Einzelne dieser Enzym-Katalysatoren werden anschliessend gereinigt und mit verschiedenen spektroskopischen Methoden charakterisiert. Die detaillierten chemisch-physikalischen Analysen umfassen die Bestimmung von enzymkinetischen Parametern, der Molekülmasse und der Integrität der Proteinstruktur. Die Ergebnisse der individuellen Experimente werden am Schluss des Kurses von den Studierenden präsentiert. Wir erwarten, dass wir im Laufe des Praktikums neben neuen Enzymen auch neue Erkenntnisse über die Funktionsweise der untersuchten Katalysatoren erhalten werden. | |||||
| Skript | Die benötigten Unterlagen werden während des Kurses an die Teilnehmer abgegeben. | |||||
| Literatur | Generelle Literatur zu "Directed Evolution" und Chorismat-Mutasen, z.B.: – Taylor, S. V., P. Kast & D. Hilvert. 2001. Investigating and engineering enzymes by genetic selection. Angew. Chem. Int. Ed. 40: 3310-3335. – Jäckel, C., P. Kast & D. Hilvert. 2008. Protein design by directed evolution. Annu. Rev. Biophys. 37: 153-173. – Roderer, K. & P. Kast. 2009. Evolutionary cycles for pericyclic reactions – Or why we keep mutating mutases. Chimia 63: 313-317. Weitere Literaturstellen werden im ausgeteilten Skript angegeben. | |||||
| Voraussetzungen / Besonderes | - In diesem Praktikum werden Experimente durchgeführt, welche einen straffen Zeitplan und (teilweise) lange (!) Arbeitszeiten erfordern. - Die Projekte dieses Kurses sind eng gekoppelt an diejenigen des Biologie BSc Kurses "529-0739-01 Biological Chemistry B: New Enzymes from Directed Evolution Experiments", welcher als Block während des Monats November stattfindet. Während dieser Zeit werden auch gemeinsame Vorlesungen mit den Teilnehmern beider Praktika durchgeführt. Die Unterrichtssprache ist Englisch. - Die Teilnehmerzahl für den Laborkurs ist beschränkt. Eine Anmeldung kann ausschliesslich persönlich bei P. Kast vorgenommen werden und muss zwingend bis zum 1. September vor dem Herbstsemesterbeginn erfolgt sein. Bis dann wird entschieden sein, ob der Kurs durchgeführt werden kann. - Eine Anmeldung gilt prinzipiell als verbindlich für den gesamten Semesterkurs, da aufwendige Materialbestellungen und Vorbereitungsarbeiten unsererseits ausgeführt und koordiniert werden müssen, und individuelle Absenzen nach Kursbeginn den Fluss der Experimente stören. In Notfällen bitte sofort P. Kast kontaktieren. - Weitere Informationen sind verfügbar auf http://www.kast.ethz.ch/teaching.html oder direkt von P. Kast (HCI F 333, Tel. 044 632 29 08, kast@org.chem.ethz.ch). | |||||
| Master-Arbeit | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0500-10L | Master's Thesis Nur für Chemie MSc, Studienreglement 2018. Zur Master-Arbeit wird nur zugelassen, wer: a. das Bachelor-Studium erfolgreich abgeschlossen hat; b. allfällige Auflagen für die Zulassung zum Master-Studiengang erfüllt hat. Dauer der Master-Arbeit 20 Wochen. | O | 25 KP | 54D | Betreuer/innen | |
| Kurzbeschreibung | ||||||
| Lernziel | ||||||
| Wahlfächer Den Studierenden stehen der Studienstufe angemessene chemische Lehrangebote des D-CHAB zur Auswahl offen (Zulassungsbedingungen beachten). Bei Unklarheiten das Studiensekretariat kontaktieren. | ||||||
| Anorganische Chemie | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0143-01L | Inorganic and Organometallic Polymers IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | H. Grützmacher, J. Grützmacher | |
| Kurzbeschreibung | 1. Introduction: What are Inorganic Polymers 1.1. Classification, 1.2. Nomenclature, 1.3. Synthetic Strategies, 1.4. Characterisation 2. Polyphosphazenes 3. Polysiloxanes 4. Organometallic Polymers 5. Dendritic Molecules 6. Introduction to Inorganic Materials | |||||
| Lernziel | Understanding of the current literature in the field of inorganic polymers and materials. | |||||
| Skript | A manuscript will be distributed to the participants of the course. | |||||
| Literatur | Script and recent orginal literature indicated in the course. | |||||
| Voraussetzungen / Besonderes | Basis for the understanding of this lecture are the courses Allgemeine Chemie 1&2, Anorganische Chemie 1: Übergangsmetallchemie (Dozent Mezzetti). | |||||
| Organische Chemie | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0243-01L | Transition Metal Catalysis: From Mechanisms to Applications IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | B. Morandi | |
| Kurzbeschreibung | Detailed discussion of selected modern transition metal catalyzed reactions from a synthetic and mechanistic viewpoint | |||||
| Lernziel | Understanding and critical evaluation of current research in transition metal catalysis. Design of mechanistic experiments to elucidate reaction mechanisms. Synthetic relevance of transition metal catalysis. Students will also learn about writing an original research proposal during a workshop. | |||||
| Inhalt | Detailed discussion of selected modern transition metal catalyzed reactions from a synthetic and mechanistic viewpoint. Synthetic applications of these reactions. Introduction and application of tools for the elucidation of mechanisms. Selected examples of topics include: C-H activation, C-O activation, C-C activation, redox active ligands, main group redox catalysis, bimetallic catalysis. | |||||
| Skript | Lecture slides will be provided online. A Handout summarizing important concepts in organometallic and physical organic chemistry will also be provided. Useful references and handouts will also be provided during the workshop. Slides will be uploaded 1-2 days before each lecture on http://morandi.ethz.ch/education.html | |||||
| Literatur | Primary literature and review articles will be cited during the course. The following textbooks can provide useful support for the course: - Anslyn and Dougherty, Modern Physical Organic Chemistry, 1st Ed., University Science Books. - Crabtree R., The Organometallic Chemistry of the Transition Metals, John Wiley & Sons, Inc. - Hartwig J., Organotransition Metal Chemistry: From Bonding to Catalysis, University Science Books. - J. P. Collman, L. S. Hegedus, J. R. Norton, R. G. Finke, Principles and Applications of Organotransition Metal Chemistry. | |||||
| Voraussetzungen / Besonderes | Required level: Courses in organic and physical chemistry (kinetics in particular) of the first and second year as well as ACIII Special requirement: each participant will have to come up with an independent research proposal to be presented orally (or handed in in written form) at the end of the semester. A dedicated workshop will be organized in the middle of the semester to introduce the students to proposal writing and presentation. | |||||
| 529-0233-01L | Organic Synthesis: Methods and Strategies IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | E. M. Carreira | |
| Kurzbeschreibung | The complex relation between structural analysis, methods leading to desired transformations, and insight into reaction mechanisms is exemplified. Relations between retrosynthetic analysis of target structures, synthetic methods and their combination in a synthetic strategy. | |||||
| Lernziel | Extension and deepening of the knowledge in organic synthesis and the principles of structure and reactivity. | |||||
| Inhalt | Begriffe der Planung (Strategie und Taktik) der organischen Synthese, Retrosynthetische Analyse, Vertiefung der Beziehungen zwischen Struktur und Reaktivität im Zusammenhang mit der Synthese organischer Verbindungen zunehmender Komplexität. Vertiefung und Ergänzung der Kenntnisse synthetischer Methoden. | |||||
| Literatur | K. C. Nicolaou, E. J. Sorensen, Classics in Total Synthesis, Wiley-VCH 1996. K. C. Nicolaou, S. A. Snyder, Classics in Total Synthesis II, Wiley-VCH 2003. K. C. Nicolaou, J. Chen, Classics in Total Synthesis III, Wiley-VCH 2011. | |||||
| Voraussetzungen / Besonderes | OC I-IV | |||||
| 529-0241-10L | Advanced Methods and Strategies in Synthesis IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure you register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | J. W. Bode | |
| Kurzbeschreibung | Advanced Modern Methods and Strategies in Synthesis | |||||
| Lernziel | Kenntnis der modernen Methoden der asymmetrischen Synthese, der enantioselektiven Katalyse, und organische Reactionsmechanismus. | |||||
| Inhalt | Aktuelle Trends in Methoden für und Annäherungen an die Synthese von komplexen Naturstoffen, Pharmazeutika und biologischen Molekülen, Fragmentkopplungs- und Schutzgruppenstrategien; chemische Ligation und Biomolekülsynthese; enantioselektive Katalyse einschließlich Ligandendesign und -optimierung; Kreuzkupplungsreaktionen voraktivierter Vorstufen; C-H-Aktivierung und Oxidationen; Bausteinsynthese mit chiralen Auxilliaren und Reagenzien; neue Konzepte in der asymmetrischen Katalyse. Analyse von Schlüsselliteratur inklusive der Erkennung von Trends, bedeutenden Präzedenzfällen und neu aufkommenden Gebieten wird hervorgehoben. | |||||
| Skript | will be provided in class and online | |||||
| Literatur | Suggesting Textbooks 1. Walsh and Kozlowski, Fundamentals of Asymmetric Catalysis, 1st Ed., University Science Books, 2009. 2. Anslyn and Dougherty, Modern Physical Organic Chemistry, 1st Ed., University Science Books, 2006. | |||||
| Physikalische Chemie | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0433-01L | Advanced Physical Chemistry: Statistical Thermodynamics IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | G. Jeschke, J. Richardson | |
| Kurzbeschreibung | Introduction to statistical mechanics and thermodynamics. Prediction of thermodynamic and kinetic properties from molecular data. | |||||
| Lernziel | Introduction to statistical mechanics and thermodynamics. Prediction of thermodynamic and kinetic properties from molecular data. | |||||
| Inhalt | Basics of statistical mechanics and thermodynamics of classical and quantum systems. Concept of ensembles, microcanonical and canonical ensembles, ergodic theorem. Molecular and canonical partition functions and their connection with classical thermodynamics. Quantum statistics. Translational, rotational, vibrational, electronic and nuclear spin partition functions of gases. Determination of the equilibrium constants of gas phase reactions. Description of ideal gases and ideal crystals. Lattice models, mixing entropy of polymers, and entropic elasticity. | |||||
| Skript | See homepage of the lecture. | |||||
| Literatur | See homepage of the lecture. | |||||
| Voraussetzungen / Besonderes | Chemical Thermodynamics, Reaction Kinetics, Molecular Quantum Mechanics and Spectroscopy; Mathematical Foundations (Analysis, Combinatorial Relations, Integral and Differential Calculus) | |||||
| 529-0443-01L | Advanced Magnetic Resonance IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure you register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | B. H. Meier, M. Ernst, T. Wiegand | |
| Kurzbeschreibung | The course is for advanced students and covers selected topics from magnetic resonance spectroscopy. This year, the lecture will introduce and discuss the concepts and applications of Biological Magnetic Resonance in the solid-state. | |||||
| Lernziel | The aim of the course is to the students with the concepts of high-resolution solid-state NMR as a method to describe structure and dynamics of biomolecules and their complexes. During the hands-on part of the lecture course, actual spectra will be analysed. | |||||
| Inhalt | Topics covered: 1) Basics of Protein Structure 2) A Summary of Basic NMR 3) Anisotropic Interactions in NMR and their Information Contents 4) MAS, Decoupling and Recoupling 5) Proton Detection vs. Carbon Detection 6) Assignment Strategies 7) Hands-on: The Assignment of HET-s 8) Structure Calculation Concepts 9) Hands-on: The structure of HET-s 10) Characterising the Molecular Dynamics 11) Hands-on: the Dynamics of HET-s 12) What are the limits? Prerequisite: A basic knowledge of NMR, e.g. as covered in the Lecture Physical Chemistry IV, or the book by Malcolm Levitt. | |||||
| Skript | A script which covers the topics will be distributed in the lecture and will be accessible through the web page http://www.ssnmr.ethz.ch/education/ | |||||
| 529-0445-01L | Advanced Optics and Spectroscopy IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | R. Signorell, G. David | |
| Kurzbeschreibung | This course provides an introduction to the interaction of light with nano- and microparticles followed by an overview of applications of current interest. Examples range from nanoparticles for medical applications and sensing to the role of the interaction of solar radiation with aerosol particles and cloud droplets for the climate. | |||||
| Lernziel | The students will be introduced to the basic concepts of the interaction of light with nano- and microparticles. The combination of basic concepts with different applications will enable students to apply their knowledge to new problems in various fields where nanoscale objects play a role. | |||||
| Inhalt | Light interacts surprisingly differently with small particles than with bulk or with gas phase materials. The first part of the course provides a basic but rigorous introduction into the interaction of light with nano- and microparticles. The emphasis is on the classical treatment of absorption and scattering of light by small particles. The strengths and limits of this conventional approach will be discussed. The second part of the course is devoted to a broad range of applications. Here topics include: Plasmon resonances in metallic systems, metallo-dielectric nanoparticles for medical applications, the use of lasers for optical trapping and characterization of single particles, vibrational excitons in dielectric nanoparticles, interaction of light with aerosol particles and cloud droplets for remote sensing applications and climate predictions, characterization of ultrafine aerosol particles by photoemission using velocity map imaging. | |||||
| Skript | will be distributed during the course | |||||
| Literatur | Basics: Absorption and Scattering of Light by Small Particles, C. F. Bohren and D. R. Huffman, John Wiley & Sons, Inc. Applications: References will be provided during the course. | |||||
| Analytische Chemie | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0043-01L | Analytical Strategy IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | R. Zenobi, M. Badertscher, K. Eyer, G. Goubert, D. Günther | |
| Kurzbeschreibung | Selbständige Erarbeitung von Lösungsvorschlägen für konkrete analytische Fragestellungen. | |||||
| Lernziel | Fähigkeit zur selbständigen Erarbeitung von Lösungsvorschlägen für konkrete analytische Fragestellungen. | |||||
| Inhalt | Selbständiges Erarbeiten von Strategien zum optimalen Einsatz von chemischen, biochemischen und physikalisch-chemischen Methoden der Analytik zur Lösung vorgegebener Probleme. Zusätzlich zu den Dozenten präsentieren Experten aus Industrie und Behörden konkrete analytische Problemstellungen aus ihrem Tätigkeitsbereich. Grundlagen der Probenahme. Aufbau und Einsatz mikroanalytischer Systeme. | |||||
| Skript | Kopien der Aufgabenstellungen und Lösungsblätter werden kostenlos abgegeben | |||||
| Voraussetzungen / Besonderes | Teilnahmebedingungen: Besuch der Veranstaltungen 529-0051-00 "Analytische Chemie I (3. Semester)" 529-0058-00 "Analytische Chemie II (4. Semester)" (oder äquivalent) | |||||
| 529-0049-00L | Analytical Methods for Characterization of Nanoparticles and Nanomaterials Findet dieses Semester nicht statt. | W | 2 KP | 2G | ||
| Kurzbeschreibung | Introduction to modern analytical methods used to fully characterize and identify nano-engineered materials and systems. | |||||
| Lernziel | Understanding of analytical concepts used in nanotechnology, In-depth knowledge of most important methods used in industry and research, Introduction to selected industrial applications, Basic knowledge of production mechanisms of nano-engineered materials. | |||||
| Inhalt | Nanotechnology is the basis of many main technological innovations of the 21st century. After more than twenty years of research, nanotechnologies are now increasingly employed for commercial use: they are used in hundreds of everyday consumer products, such as cosmetics, food, automotive, electronics and medical products. Nanoparticles can contribute to stronger, lighter, cleaner, smarter, better, etc. products. Besides these positive effects, relatively little is still known about potential health and environmental effects and risks of such small nano-sized particles. Therefore, a lot of different industry customers are forced nowadays to monitor and regulate the size and concentration of nanoparticles in their nano-enabled products. Above and beyond these regulatory requirements, most industries employing nanoparticles need to be able to online measure nanoparticles to meet their requirements towards quality control and production efficiency. All these requirements demand new precise, accurate, fast and innovative analysis methods to fully characterize nanoparticles in real-time and during the manufacturing process. | |||||
| Skript | Lecture notes will be provided | |||||
| Voraussetzungen / Besonderes | Prerequisites: 529-0051-00 "Analytical Chemistry I (3. Semester)", 529-0058-00 "Analytical Chemistry II (4. Semester)" (or equivalent) | |||||
| Biologische Chemie | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0733-01L | Enzymes IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | D. Hilvert | |
| Kurzbeschreibung | Vermittlung eines Überblicks über die Chemie von Enzymen, enzymkatalysierten Reaktionen, metabolischen Prozessen. | |||||
| Lernziel | Vermittlung eines Überblicks über die Chemie von Enzymen, enzymkatalysierten Reaktionen, metabolischen Prozessen. | |||||
| Inhalt | Prinzipien der enzymatischen Katalyse, Enzymkinetiken, Mechanismen enzymkatalysierter Reaktionen (Gruppentransferreaktion, Kohlenstoff-Kohlenstoff-Bindungsknüpfungen, Eliminierungen, Isomerisierungen und Umlagerungen), Kofaktorenchemie, Enzyme in der organischen Synthese und in der Naturstoffbiosynthese, katalytische Antikörper. | |||||
| Skript | A script will not be handed out. | |||||
| Literatur | General: T. Bugg, An Introduction to Enzyme and Coenzyme Chemistry, Blackwell Science Ltd., Oxford, 1997. In addition, citations from the original literature relevant to the individual lectures will be assigned weekly. | |||||
| Chemische Aspekte der Energie | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 151-0209-00L | Renewable Energy Technologies | W | 4 KP | 3G | A. Steinfeld | |
| Kurzbeschreibung | Renewable energy technologies: solar, biomass, wind, geothermal, hydro, waste-to-energy. Focus is on the engineering aspects. | |||||
| Lernziel | Students learn the potential and limitations of renewable energy technologies and their contribution towards sustainable energy utilization. | |||||
| Voraussetzungen / Besonderes | Prerequisite: strong background on the fundamentals of engineering thermodynamics, equivalent to the material taught in the courses Thermodynamics I, II, and III of D-MAVT. | |||||
| Chemische Kristallographie | ||||||
| Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
| 529-0029-01L | Structure Determination IMPORTANT NOTICE for Chemistry students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in Chemistry regulations 2005. | W | 6 KP | 3G | M. D. Wörle, N. Trapp | |
| Kurzbeschreibung | Advanced X-ray crystal structure analysis | |||||
| Lernziel | Erweitertes Verständnis der in der Kristallstrukturanalyse angewendeten Methoden, Auswertung von Resultaten. | |||||
| Inhalt | Zusammenfassung der kristallographischen Grundbegriffe und der Prinzipien der Diffraktion. Anorganische Strukturchemie: Packungstypen, Ionenkristalle, covalente Netzwerke, intermetallische Verbindungen. Übersicht über Pulverdiffraktometrie und Anwendung der Kristallchemie in der Strukturanalyse polykristalliner Phasen. Sicheres Arbeiten mit Röntgenstrahlen, Kristallwachstum, Auswahl und Montage auf die Instrumente, Strategien der Diffraktionsmessung, Korrekturen. Lösungsmethoden des kristallographischen Phasenproblems: Pattersonfunktion, Schweratomtechnik, Fouriersynthesen, direkte Methoden. Aufstellung von Strukturmodellen und Verfeinerung, Fehlordnung, Verzwillingung, Symmetrieprobleme, Interpretation anisotroper atomarer Verschiebungsparameter. Interpretation der Resultate und deren Bedeutung für die Chemie, Kontrolle und Publikation der Resultate, kritische Diskussion publizierter Kristallstrukturdaten. | |||||
| Skript | Unterlagen werden in loser Form abgegeben. | |||||
| Literatur | Haupttext (1) W. Massa, "Kristallstrukturbestimmung", 7. Auflage, 2011, Teubner. (2) J.D. Dunitz, "X-ray Analysis and the Structure of Organic Molecules", 1995, Verlag HCA. Zusätzliche Literatur (3) C. Hammond, "The Basics of Crystallography and Diffraction", 2nd Ed., 2001, International Union of Crystallography Texts on Crystallography 5, Oxford University Press. (4) J.P. Glusker, M. Lewis & M. Rossi, "Crystal Structure Analysis for Chemists and Biologists", 1994, VCH Publishers. (5) D. Blow, "Outline of Crystallography for Biologists", 2002 Oxford University Press. (6) D. Schwarzenbach, "Kristallographie", 2001, Springer Verlag. (7) C. Giacovazzo, H.L. Monaco, G. Artioli, D. Viterbo, G. Ferraris, G. Gilli, G. Zanotti & M. Catti, Fundamentals of Crystallography", edited by C. Giacovazzo, 2nd Ed., 2002, International Union of Crystallography Texts on Crystallography 7, Oxford University Press. (8) W. Clegg, A.J. Blake, R.O. Gould & P. Main, "Crystal Structure Analysis - Principles and Practice", edited by W. Clegg, 2001, International Union of Crystallography Texts on Crystallography 6, Oxford University Press. (9) J.P. Glusker & K.N. Trueblood, "Crystal Structure Analysis - A Primer", 2nd Ed., 1985, Oxford University Press. (10) G. H. Stout, L. H. Jensen: X-Ray Structure Determination, J. Wiley & Sons, 1989. (11) M. M. Woolfson: X-Ray Crystallography, Cambridge University Press, 1970. | |||||
| Voraussetzungen / Besonderes | Die einführenden Beispiele und Strukturverfeinerungen können selbst auf Personalcomputer ausgeführt werden. Voraussetzungen: Grundlagen der Kristallstrukturanalyse (529-0039-00L). | |||||
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