Maksym Kovalenko: Katalogdaten im Frühjahrssemester 2021

NameHerr Prof. Dr. Maksym Kovalenko
LehrgebietAnorganische Funktionsmaterialien
Adresse
Lab. für Anorganische Chemie
ETH Zürich, HCI H 139
Vladimir-Prelog-Weg 1-5/10
8093 Zürich
SWITZERLAND
Telefon+41 44 633 41 56
E-Mailmvkovalenko@ethz.ch
DepartementChemie und Angewandte Biowissenschaften
BeziehungOrdentlicher Professor

NummerTitelECTSUmfangDozierende
529-0122-00LInorganic Chemistry II3 KP3GM. Kovalenko, K. Kravchyk
KurzbeschreibungThe lecture is based on Inorganic Chemistry I and addresses an enhanced understanding of the symmetry aspects of chemical bonding of molecules and translation polymers, i.e. crystal structures.
LernzielThe lecture follows Inorganic Chemistry I and addresses an enhanced understanding of the symmetry aspects of chemical bonding of molecules and translation polymers.
InhaltSymmetry aspects of chemical bonding, point groups and representations for the deduction of molecular orbitals, energy assessment for molecules and solids, Sanderson formalism, derivation and understanding of band structures, densities of states, overlap populations, crystal symmetry, basic crystal structures and corresponding properties, visual representations of crystal structures.
Skriptsee Moodle
Literatur1. I. Hargittai, M. Hargittai, "Symmetry through the Eyes of a Chemist", Plenum Press, 1995;
2. R. Hoffmann, "Solids and Surfaces", VCH 1988;
3. U. Müller, "Anorganische Strukturchemie", 6. Auflage, Vieweg + Teubner 2008
Voraussetzungen / BesonderesRequirements: Inorganic Chemistry I
529-0134-01LFunctional Inorganics6 KP3GM. Kovalenko, K. Kravchyk, T. Lippert, G. Raino
KurzbeschreibungThis course covers the synthesis, properties and applications of inorganic materials. In particular, the focus is on photo-active coordination compounds, quasicrystals, nanocrystals (including nanowires), molecular precursors for inorganic materials and metal-organic frameworks.
LernzielUnderstanding 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.
Inhalt(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.
Skriptwill be distributed during lectures
Literaturwill be suggested in the lecture notes
Voraussetzungen / BesonderesNo special knowledge beyond undergraduate curriculum
529-0199-00LInorganic and Organometallic Chemistry0 KP2KH. Grützmacher, C. Copéret, D. Günther, M. Kovalenko, A. Mezzetti, V. Mougel
Kurzbeschreibung
Lernziel
529-0948-00LSolid State Chemistry Belegung eingeschränkt - Details anzeigen
Belegung nur möglich bis zum 01.02.2021 mit Bevorzugung von Teilnehmern, welche die Vorlesung «Inorganic Chemistry II» besucht haben. Andere Anmelder können nur bei unbelegten Plätzen berücksichtigt werden
(Anzahl der Teilnehmer auf 20 pro Jahr limitiert!).

Elektronische Einschreibung obligatorisch
(Ausgenommen ETH-externe Teilnehmer).
3 KP6PM. Kovalenko, M. Kotyrba, S. Yakunin
KurzbeschreibungAn introduction to crystal growth with the Bridgman-Stockbarger technique and physical characterization of single crystals.
LernzielThe practical laboratory course gives an insight into the growth of single crystals and their applications. Focus lies on the growth of semiconductor crystals and the measurement of their physical (optical & electronic) properties. The complete work is documented in a detailed scientific report.
InhaltThe growth of perovskite (CsPbBr3) semiconductor crystals using the Bridgman-Stockbarger technique as a model system for single crystals grown from the melt. The preparation of crystals for physical measurements through cutting and polishing. Measuring optical characteristics (absorption) as well as electronic properties, including current-voltage (IV) measurements, time-of-flight, charge carrier recombination, charge extraction efficiencies, and photodetection.
SkriptElectronic version of the script will be provided.
LiteraturAll references in the script will be provided in .pdf-form, no other sources are needed.
Voraussetzungen / BesonderesSchutzkonzept: https://chab.ethz.ch/studium/bachelor1.html