Search result: Catalogue data in Spring Semester 2017
Chemistry Master | ||||||
Core Subjects | ||||||
Inorganic Chemistry | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
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529-0134-00L | Functional Inorganics | W | 7 credits | 3G | M. Kovalenko, T. Lippert, Y. Romanyuk | |
Abstract | This course will cover the synthesis, properties and applications of inorganic materials. In particular, the focus will be on photo-active coordination compounds, quasicrystals, nanocrystals (including nanowires), molecular precursors for inorganic materials and metal-organic frameworks. | |||||
Objective | Understanding the structure-property relationship and the design principles of modern inorganic materials for prospective applications in photovoltaics, electrochemical energy storage (e.g. Li-ion batteries), thermoelectrics and photochemical and photoelectrochemical water splitting. | |||||
Content | (A) Introduction into the synthesis and atomic structure of modern molecular and crystalline inorganic materials. -Quasicrystals -Nanocrystals, including shape engineering -Molecular precursors (including organometallic and coordination compounds) for inorganic materials -Metal-organic frameworks -Photoactive molecules (B) Applications of inorganic materials: -photovoltaics -Li-ion batteries -Thermoelectrics -Photochemical and photoelectrochemical water splitting -Light-emitting devices etc. | |||||
Lecture notes | will be distributed during lectures | |||||
Literature | will be suggested in the lecture notes | |||||
Prerequisites / Notice | No special knowledge beyond undergraduate curriculum | |||||
Electives | ||||||
Inorganic Chemistry | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
529-0134-00L | Functional Inorganics | W | 7 credits | 3G | M. Kovalenko, T. Lippert, Y. Romanyuk | |
Abstract | This course will cover the synthesis, properties and applications of inorganic materials. In particular, the focus will be on photo-active coordination compounds, quasicrystals, nanocrystals (including nanowires), molecular precursors for inorganic materials and metal-organic frameworks. | |||||
Objective | Understanding the structure-property relationship and the design principles of modern inorganic materials for prospective applications in photovoltaics, electrochemical energy storage (e.g. Li-ion batteries), thermoelectrics and photochemical and photoelectrochemical water splitting. | |||||
Content | (A) Introduction into the synthesis and atomic structure of modern molecular and crystalline inorganic materials. -Quasicrystals -Nanocrystals, including shape engineering -Molecular precursors (including organometallic and coordination compounds) for inorganic materials -Metal-organic frameworks -Photoactive molecules (B) Applications of inorganic materials: -photovoltaics -Li-ion batteries -Thermoelectrics -Photochemical and photoelectrochemical water splitting -Light-emitting devices etc. | |||||
Lecture notes | will be distributed during lectures | |||||
Literature | will be suggested in the lecture notes | |||||
Prerequisites / Notice | No special knowledge beyond undergraduate curriculum | |||||
529-0144-00L | NMR Spectroscopy in Inorganic Chemistry | W | 7 credits | 3G | R. Verel | |
Abstract | Theory and applications of NMR spectroscopy with a focus of its use to problems in Inorganic Chemistry. The use of the Bloch Equations to describe broadband and selective excitation, measurement techniques and processing strategies of NMR data, applications of NMR to the study of molecular structure, chemical exchange processes, diffusion spectroscopy, and solid-state NMR techniques. | |||||
Objective | In depth understanding of both practical and theoretical aspects of solution and solid-state NMR and its application to problems in Inorganic Chemistry | |||||
Content | Selection of the following themes: 1. Bloch Equations and its use to understand broadband and selective pulses. 2. Measurement techniques and processing strategies of NMR data. 3. Applications of NMR to the study of molecular structure: Experiments and strategies to solve problems in Inorganic Chemistry. 4. Application of NMR to the study of chemical exchange processes. 5. Application of NMR to the study of self-diffusion and the determination of diffusion coefficients. 6. Differences and similarities between fundamental interactions in solution and solid-state NMR 7. Experimental techniques in solid-state NMR (Magic Angle Spinning, Cross Polarization, Decoupling and Recoupling Techniques, MQMAS) 8. The use of Dynamic Nuclear Polarization for the study of surfaces. | |||||
Lecture notes | A handout is provided during the lectures. It is expected that the students will consult the accompanying literature as specified during the lecture. | |||||
Literature | Specified during the lecture | |||||
Prerequisites / Notice | 529-0432-00 Physikalische Chemie IV: Magnetische Resonanz 529-0058-00 Analytische Chemie II (or equivalent) | |||||
Materials Science | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
529-0941-00L | Introduction to Macromolecular Chemistry | W | 4 credits | 3G | A. D. Schlüter | |
Abstract | Basic definitions, types of polyreactions, constitution of homo- and copolymers, networks, configurative and conformative aspects, contour length, coil formation, mobility, glass temperature, rubber elasticity, molecular weight distribution, energetics of and examples for polyreactions. | |||||
Objective | Understanding the significance of molecular size, constitution, configuration and conformation of synthetic and natural macromolecules for their specific physical and chemical properties. | |||||
Content | This introductory course on macromolecular chemistry discusses definitions, introduces types of polyreactions, and compares chain and step-growth polymerizations. It also treats the constitution of polymers, homo- and copolymers, networks, configuration and conformation of polymers. Topics of interest are contour length, coil formation, the mobility in polymers, glass temperature, rubber elasticity, molecular weight distribution, energetics of polyreactions, and examples for polyreactions (polyadditions, polycondensations, polymerizations). Selected polymerization mechanisms and procedures are discussed whenever appropriate throughout the course. Some methods of molecular weight determination are introduced. | |||||
Lecture notes | Course materials (consisting of personal notes and distributed paper copies) are sufficient for exam preparation. | |||||
Prerequisites / Notice | The course will be taught in English. Complicated expressions will also be given in German. Questions are welcome in English or German. The written examination will be in English, answers in German are acceptable. A basic chemistry knowledge is required. PhD students who need recognized credit points are required to pass the written exam. | |||||
227-0390-00L | Elements of Microscopy | W | 4 credits | 3G | M. Stampanoni, G. Csúcs, A. Sologubenko | |
Abstract | The lecture reviews the basics of microscopy by discussing wave propagation, diffraction phenomena and aberrations. It gives the basics of light microscopy, introducing fluorescence, wide-field, confocal and multiphoton imaging. It further covers 3D electron microscopy and 3D X-ray tomographic micro and nanoimaging. | |||||
Objective | Solid introduction to the basics of microscopy, either with visible light, electrons or X-rays. | |||||
Content | It would be impossible to imagine any scientific activities without the help of microscopy. Nowadays, scientists can count on very powerful instruments that allow investigating sample down to the atomic level. The lecture includes a general introduction to the principles of microscopy, from wave physics to image formation. It provides the physical and engineering basics to understand visible light, electron and X-ray microscopy. During selected exercises in the lab, several sophisticated instrument will be explained and their capabilities demonstrated. | |||||
Literature | Available Online. | |||||
402-0468-15L | Nanomaterials for Photonics | W | 6 credits | 2V + 1U | R. Grange | |
Abstract | The lecture describes various nanomaterials (semiconductor, metal, dielectric, carbon-based...) for photonic applications (optoelectronics, plasmonics, photonic crystal...). It starts with nanophotonic concepts of light-matter interactions, then the fabrication methods, the optical characterization techniques, the description of the properties and the state-of-the-art applications. | |||||
Objective | The students will acquire theoretical and experimental knowledge in the different types of nanomaterials (semiconductors, metals, dielectric, carbon-based, ...) and their uses as building blocks for advanced applications in photonics (optoelectronics, plasmonics, photonic crystal, ...). Together with the exercises, the students will learn (1) to read, summarize and discuss scientific articles related to the lecture, (2) to estimate order of magnitudes with calculations using the theory seen during the lecture, (3) to prepare a short oral presentation about one topic related to the lecture, and (4) to imagine a useful photonic device. | |||||
Content | 1. Introduction to Nanomaterials for photonics a. Classification of the materials in sizes and speed... b. General info about scattering and absorption c. Nanophotonics concepts 2. Analogy between photons and electrons a. Wavelength, wave equation b. Dispersion relation c. How to confine electrons and photons d. Tunneling effects 3. Characterization of Nanomaterials a. Optical microscopy: Bright and dark field, fluorescence, confocal, High resolution: PALM (STORM), STED b. Electron microscopy : SEM, TEM c. Scanning probe microscopy: STM, AFM d. Near field microscopy: SNOM e. X-ray diffraction: XRD, EDS 4. Generation of Nanomaterials a. Top-down approach b. Bottom-up approach 5. Plasmonics a. What is a plasmon, Drude model b. Surface plasmon and localized surface plasmon (sphere, rod, shell) c. Theoretical models to calculate the radiated field: electrostatic approximation and Mie scattering d. Fabrication of plasmonic structures: Chemical synthesis, Nanofabrication e. Applications 6. Organic nanomaterials a. Organic quantum-confined structure: nanomers and quantum dots. b. Carbon nanotubes: properties, bandgap description, fabrication c. Graphene: motivation, fabrication, devices 7. Semiconductors a. Crystalline structure, wave function... b. Quantum well: energy levels equation, confinement c. Quantum wires, quantum dots d. Optical properties related to quantum confinement e. Example of effects: absorption, photoluminescence... f. Solid-state-lasers : edge emitting, surface emitting, quantum cascade 8. Photonic crystals a. Analogy photonic and electronic crystal, in nature b. 1D, 2D, 3D photonic crystal c. Theoretical modeling: frequency and time domain technique d. Features: band gap, local enhancement, superprism... 9. Optofluidic a. What is optofluidic ? b. History of micro-nano-opto-fluidic c. Basic properties of fluids d. Nanoscale forces and scale law e. Optofluidic: fabrication f. Optofluidic: applications g. Nanofluidics 10. Nanomarkers a. Contrast in imaging modalities b. Optical imaging mechanisms c. Static versus dynamic probes | |||||
Lecture notes | Slides and book chapter will be available for downloading | |||||
Literature | References will be given during the lecture | |||||
Prerequisites / Notice | Basics of solid-state physics (i.e. energy bands) can help | |||||
Laboratory Courses and Research Projects | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
529-0200-00L | Research Project I | O | 16 credits | 16A | Professors | |
Abstract | 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. | |||||
Objective | Students are accustomed to scientific work and they get to know one specific research field. | |||||
529-0201-00L | Research Project II | O | 17 credits | 17A | Professors | |
Abstract | 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. | |||||
Objective | Students are accustomed to scientific work and they get to know one specific research field. | |||||
GESS Science in Perspective | ||||||
» Recommended Science in Perspective (Type B) for D-CHAB | ||||||
» see Science in Perspective: Type A: Enhancement of Reflection Capability | ||||||
» see Science in Perspective: Language Courses ETH/UZH | ||||||
Master's Thesis | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
529-0500-00L | Master's Thesis Only students who fulfill the following criteria are allowed to begin with their Master's thesis: a. successful completion of the Bachelor programme; b. fulfilling of any additional requirements necessary to gain admission to the Master programme. Duration of the Master's Thesis 16 weeks. | O | 20 credits | 43D | Professors | |
Abstract | In the Master thesis students prove their ability to independent, structured and scientific working. The Master thesis is usually carried out in a core or optional subject area as chosen by the student. | |||||
Objective | In the Master Thesis students prove their ability to independent, structured and scientific working. | |||||
Course Units for Additional Admission Requirements The courses below are only available for MSc students with additional admission requirements. | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
529-0051-AAL | Analytical Chemistry I Enrolment ONLY for MSc students with a decree declaring this course unit as an additional admission requirement. Any other students (e.g. incoming exchange students, doctoral students) CANNOT enrol for this course unit. | E- | 3 credits | 6R | D. Günther, R. Zenobi | |
Abstract | Introduction into the most important spectroscopical methods and their applications to gain structural information. | |||||
Objective | Knowledge about the necessary theoretical background of spectroscopical methods and their practical applications | |||||
Content | Application oriented basics of organic and inorganic instrumental analysis and of the empirical employment of structure elucidation methods: Mass spectrometry: Ionization methods, mass separation, isotope signals, rules of fragmentation, rearrangements. NMR spectroscopy: Experimental basics, chemical shift, spin-spin coupling. IR spectroscopy: Revisiting topics like harmonic oscillator, normal vibrations, coupled oscillating systems (in accordance to the basics of the related lecture in physical chemistry); sample preparation, acquisition techniques, law of Lambert and Beer, interpretation of IR spectra; Raman spectroscopy. UV/VIS spectroscopy: Basics, interpretation of electron spectra. Circular dichroism (CD) und optical rotation dispersion (ORD). Atomic absorption, emission, and X-ray fluorescence spectroscopy: Basics, sample preparation. | |||||
Lecture notes | Script will be provided for factory costs. | |||||
Literature | - R. Kellner, J.-M. Mermet, M. Otto, H. M. Widmer (Eds.) Analytical Chemistry, Wiley-VCH, Weinheim, 1998; - D. A. Skoog und J. J. Leary, Instrumentelle Analytik, Springer, Heidelberg, 1996; - M. Hesse, H. Meier, B. Zeeh, Spektroskopische Methoden in der organischen Chemie, 5. überarbeitete Auflage, Thieme, Stuttgart, 1995 - E. Pretsch, P. Bühlmann, C. Affolter, M. Badertscher, Spektroskopische Daten zur Strukturaufklärung organischer verbindungen, 4. Auflage, Springer, Berlin/Heidelberg, 2001- Kläntschi N., Lienemann P., Richner P., Vonmont H: Elementanalytik. Instrumenteller Nachweis und Bestimmung von Elementen und deren Verbindungen. Spektrum Analytik, 1996, Hardcover, 339 S., ISBN 3-86025-134-1. | |||||
Prerequisites / Notice | Excercises are integrated in the lectures. In addition, attendance in the lecture 529-0289-00 "Instrumental analysis of organic compounts" (4th semester) is recommended. | |||||
529-0122-AAL | Inorganic Chemistry II Enrolment ONLY for MSc students with a decree declaring this course unit as an additional admission requirement. Any other students (e.g. incoming exchange students, doctoral students) CANNOT enrol for this course unit. | E- | 3 credits | 6R | M. Kovalenko | |
Abstract | The course covers fundamental aspects and concepts of solid-state chemistry essential for understanding the structure and properties of solids, from bulk to nanostructures. The goal is to establish the relationship between the atomic and mesoscale structure and electrical, magnetic and optical properties of solids. | |||||
Objective | To establish understanding of the atomic structure and chemical bonding in solids, methods of characterizing the structure and physical properties of the solids, and the ability to link structure with the property for a given class of materials. A conceptual understanding of the chemistry of nanoscale inorganic materials is targeted as well. | |||||
Content | Topics include: basic crystallography, including space groups, close packed structure models, important crystal structures and properties associated with them, crystal defects, synthesis methods for solids, characterization of solids by diffraction, microscopy and spectroscopy methods, bonding in solids, phase diagrams, physical properties (electrical, magnetic and optic). | |||||
Lecture notes | on Moodle | |||||
Literature | 1.West, Anthony R. (2014), Solid State Chemistry and its Applications, 2nd Edition, Student Edition, Wiley-Blackwell, Chichester. | |||||
Prerequisites / Notice | Requirements: Inorganic Chemistry I | |||||
529-0132-AAL | Inorganic Chemistry III: Organometallic Chemistry and Homogeneous Catalysis Enrolment ONLY for MSc students with a decree declaring this course unit as an additional admission requirement. Any other students (e.g. incoming exchange students, doctoral students) CANNOT enrol for this course unit. | E- | 4 credits | 9R | A. Togni, A. Mezzetti | |
Abstract | Fundamental aspects of the organometallic chemistry ot the transition elements. Mechanistic homogeneous catalysis including oxidative additions, reductive eliminations and insertion reactions. Catalytic hydrogenation, carbonylation, C-C bond-forming and related reactions. | |||||
Objective | Towards an understanding of the fundamental coordination-chemical and mechanistic aspects of transition-metal chemistry relevant to homogeneous catalysis. | |||||
Content | Fundamental aspects of the organometallic chemistry ot the transition elements. Mechanistic homogeneous catalysis including oxidative additions, reductive eliminations and insertion reactions. Catalytic hydrogenation, carbonylation, C-C bond-forming and related reactions. | |||||
Literature | 1) Robert H. Crabtree, The Organometallic Chemistry of the Transition Metals, 6th Edition, Wiley, 2014, ISBN: 978-1-118-13807-6. A relatively concise but excellent introduction to organometallic chemistry. Strong textbook character, available as E-book 2) John F. Hartwig, Organotransition Metal Chemistry. From Bonding to Catalysis, University Science Books, 2010, ISBN: 978-1-891389-53-5. A more comprehensive standard work on organometallic chemistry. Several chapters written by various authors, partly specialized review-article style. |
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