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Lecturer(s)
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Šabata Pavel, PaedDr. CSc.
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Course content
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1st lecture Atomic nucleus - the history, composition, properties, models, isotopes. 2nd lecture Nuclear reactions - classification, radioactivity, mechanism, kinetics, reaction energy, cross section, fission, thermonuclear reactions, chemistry of atoms incurred by nuclear reactions, transuranides. 3rd lecture Interaction of nuclear radiation with substance (matter) - the interaction of individual types of radiation, detection, chemical and biological effects. 4th lecture Application of nuclear chemistry - activation methods, separation of nuclides, production of radionuclides, the method of labeled compounds, nuclear analysis of samples. 5th lecture Nuclear energetics 6th lecture Excursions 7th lecture Chemical periodicity 8th lecture Acid-base properties 9th lecture Redox properties 10th lecture Chemistry of nonmetals 11th lecture Chemistry of metals 12th lecture Coordination
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Learning activities and teaching methods
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Interactive lecture, Students' portfolio, Students' self-study
- Presentation preparation (report) (1-10)
- 10 hours per semester
- Contact hours
- 26 hours per semester
- Preparation for an examination (30-60)
- 30 hours per semester
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| prerequisite |
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| Knowledge |
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| define and characterize transient, transient and internally transient elements |
| describe the construction of the atom and the atomic nucleus |
| explain the term radioactivity and radioactive radiation |
| Skills |
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| to estimate and compare the properties of elements based on their location in PSP |
| use chemical terminology to describe the atom |
| learning outcomes |
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| Knowledge |
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| to define basic terms and to put them in context (atomic nucleus, nuclear reactions, nuclear radiation interactions with matter, application of nuclear chemistry) |
| to describe the history, composition, properties and models of the atomic nucleus |
| categorization of nuclear reaction and explanation of mechanism, kinetics and energy of nuclear reactions |
| to explain the interaction of nuclear radiation with matter |
| describe the production of radionuclides |
| to describe basic principles of nuclear energy |
| to explain the chemical periodicity and its relation to the acid-base and redox properties of elements and their compounds |
| Skills |
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| apply acquired knowledge to solve and explain practical problems |
| teaching methods |
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| Knowledge |
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| Interactive lecture |
| Self-study of literature |
| Students' portfolio |
| assessment methods |
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| Combined exam |
| Individual presentation at a seminar |
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Recommended literature
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BACHER P. Energie pro 21. století. Agentura KRIGL, Praha, 2003. ISBN 80-902403-7-2.
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Grambal, F. Úvod do jaderné chemie. Vydavatelství UP, Olomouc, 1996. ISBN 80-7067-627-2.
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Greenwood, N., N.; Earnshaw, A. Chemie prvků I., II.. Praha: Informatorium, 1993. ISBN 80-85427-38-9.
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Hála, J. Radioaktivita, ionizující záření, jaderná energie. Konvoj, 1998.
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Majer, Vladimír. Základy jaderné chemie. Vyd. 2. přeprac. Praha : SNTL, 1981.
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Majer, Vladimír. Základy užité jaderné chemie : Vysokošk. příručka. 1. vyd. Praha : SNTL, 1985.
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MCPHERSON P. A. C. Principles Of Nuclear Chemistry (Essential Textbooks in Chemistry). WSPC (EUROPE), 2016. ISBN 978-1786340511.
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ŘÍPA M., WEINZETTL V., MLYNÁŘ J., ŽÁČEK F. Řízená termojaderná syntéza pro každého. Ústav fyziky plazmatu AV ČR, Praha, 2004. ISBN 80-902724-7-9.
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