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The basic concepts introduced in the courses of General and Inorganic Chemistry are summarized, generalized and extended using the knowledge and skills acquired in further courses following GIC=I and GIC-II: The course is devided in two units covering: (1) electronic structure of species forming the inorganic systems, (2) application of chemical thermodynamics in description of reactivity of inorganic substances. At the end the principal trends and unique properties of f-elements are discussed (this topic is not addressed in the basic courses of GIC)
Last update: Sedmidubský David (27.08.2013)
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Students will be able to: Identify the ground and excited states of atoms and molecules and to interprete spectroscopic data Construct the molecular orbitals diagrams of polyatomic molecules and complexes Perform less complicated calculations of phase and chemical equilibria in inorganic systems Interprete, complete and construct various types of phase diagrams Propose the synthesis routes, assess the reactivity and properties of coordination complexes, elemental f-elements ans their compounds Last update: TAJ101 (03.12.2013)
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R: C.E.Housecroft, A.G.Sharpe, Anorganická chemie, 4. vydání, VŠCHT Praha, 2014 R: G.Wulfsberg, Inorganic Chemistry, University Science Books, 2000, 98053513 A: R.Polák, R.Zahradník, Kvantová chemie, SNTL, 1985, 0462185 A. P.W.Atkins, Fyzikální chemie, VŠCHT Praha, 2013 A: F.Weinhold, Chemical and Phase Thermodynamics, Wiley, 2009, 9780470402368 Last update: Sedmidubský David (27.08.2013)
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To obtain the credit an active participance in the tutorials is required and tested by individual solution of several (usually four) problems, as well as the participance in most lectures. The examination is oral. Last update: Sedmidubský David (27.08.2013)
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1. Symmetry of molecules and group theory application in inorganic chemistry. 2. Ground and excited states of atoms and ions, orbital and spin momentum. 3. Electrostatic ligand field theory, weak and strong field, Tanabe-Sugano diagrams. 4. Chemical bonding in polyatomic molecules, group orbitals, variational method, effective Hamilotnian. 5. Electronic excitations, photoelectron spectroscopy, vibrational states of molecules, IR a Raman spectroscopy. 6. Bonding in coordiantion compounds, reactivity, equilibrium and kinetic aspects, organometals. 7. Energetics and thermodynamic properties of inorganic substances 8. Homogenneous equilibria in gases and liquids, balance matrices, independent reactions, equilibrium constants 9. Water and aqueous solutions, standard state, infinite dilution. models for nonideal behavior 10.Acid-base and redox equilibria in aqueous solutions, construction of Pourbaix diagrams 11.Heterogenneous equilibria in inorganic systems, phase diagram types 12.Partly open systems, log(a)-T diagrams, Kellogg and Elingham diagrams 13.Colloid systems and nanomaterials, surface energy and tension, thermodynamic consequences. 14.F-elements. Trends in properties, electronic structure, chemical bonding. Last update: Sedmidubský David (16.11.2012)
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FactSage - integrated database and calculation program for thermodynamic modeling of inorganic systems Gaussian a GaussView - programs for calculation and visualization of electron structures of molecular substances Maple Last update: Sedmidubský David (27.08.2013)
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General and inorganic chemistry II, Physical chemistry I and II, Mathematics I and II, Physics I and II. Last update: Sedmidubský David (27.08.2013)
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Teaching methods | ||||
Activity | Credits | Hours | ||
Konzultace s vyučujícími | 0.2 | 6 | ||
Účast na přednáškách | 1 | 28 | ||
Příprava na přednášky, semináře, laboratoře, exkurzi nebo praxi | 0.8 | 21 | ||
Práce na individuálním projektu | 1 | 28 | ||
Příprava na zkoušku a její absolvování | 0.5 | 14 | ||
Účast na seminářích | 0.5 | 14 | ||
4 / 4 | 111 / 112 |
Coursework assessment | |
Form | Significance |
Regular attendance | 30 |
Defense of an individual project | 40 |
Oral examination | 30 |