Daten
Offizielle Daten in der Fachveröffentlichung für das folgende akademische Jahr: 2019-2020
Lehrbeauftragte/r
-
Dr. Pál PERJÉSI
professor,
Department of Pharmaceutical Chemistry -
Semesterwochenstunden
Vorlesungen: 42
Praktika: 0
Seminare: 14
Insgesamt: 56
Fachangaben
- Kode des Kurses: OPA-ALK-T
- 4 kredit
- Pharmacy
- Basic modul
- autumn
keine
Vizsgakurzus:ja
Zahl der Kursteilnehmer für den Kurs:
min. 5 – max. 100
Thematik
The course includes selected General Chemistry topics that are essential for pharmacy students to study the Chemistry-related subjects (eg, Pharmaceutical Chemistry, Pharmaceutical Technology) in the higher semesters.
Vorlesungen
- 1. Classification of matter. Atomic structure. Electron configuration and periodicity. The periodic table. Periodic properties. - Dr. Perjési Pál
- 2. Classification of matter. Atomic structure. Electron configuration and periodicity. The periodic table. Periodic properties. - Dr. Perjési Pál
- 3. Classification of matter. Atomic structure. Electron configuration and periodicity. The periodic table. Periodic properties. - Dr. Perjési Pál
- 4. Structure of molecules. Chemical bonding. Chemical bonding theories. Valence bond theory. Hybrid orbitals. Molecular orbital theory. Moleculas geometry. - Dr. Perjési Pál
- 5. Structure of molecules. Chemical bonding. Chemical bonding theories. Valence bond theory. Hybrid orbitals. Molecular orbital theory. Moleculas geometry. - Dr. Perjési Pál
- 6. Structure of molecules. Chemical bonding. Chemical bonding theories. Valence bond theory. Hybrid orbitals. Molecular orbital theory. Moleculas geometry. - Dr. Perjési Pál
- 7. States of matter. The gaseous state. Gas laws. Intermolecular forces. The liquid state. The solid state. Phase transitions. Phase diagrams. - Dr. Almási Attila
- 8. States of matter. The gaseous state. Gas laws. Intermolecular forces. The liquid state. The solid state. Phase transitions. Phase diagrams. - Dr. Almási Attila
- 9. States of matter. The gaseous state. Gas laws. Intermolecular forces. The liquid state. The solid state. Phase transitions. Phase diagrams. - Dr. Almási Attila
- 10. Water and the aqueous solutions. Dissolution of gases, liquids and solids in liquids. Types of electrolytes. Electrolytic dissociation, degree of dissociation, conductivity, and their relationships . - Dr. Almási Attila
- 11. Water and the aqueous solutions. Dissolution of gases, liquids and solids in liquids. Types of electrolytes. Electrolytic dissociation, degree of dissociation, conductivity, and their relationships . - Dr. Almási Attila
- 12. Water and the aqueous solutions. Dissolution of gases, liquids and solids in liquids. Types of electrolytes. Electrolytic dissociation, degree of dissociation, conductivity, and their relationships . - Dr. Almási Attila
- 13. Chemical kinetics. Reaction rates. The collision theory. Rate laws and reaction mechanisms. - Dr. Perjési Pál
- 14. Chemical kinetics. Reaction rates. The collision theory. Rate laws and reaction mechanisms. - Dr. Perjési Pál
- 15. Chemical kinetics. Reaction rates. The collision theory. Rate laws and reaction mechanisms. - Dr. Perjési Pál
- 16. Chemical equilibria. LeChatelier's principle. Protolytic reactions I. Ionization of water. The pH scale. - Dr. Lóránd Tamás
- 17. Chemical equilibria. LeChatelier's principle. Protolytic reactions I. Ionization of water. The pH scale. - Dr. Lóránd Tamás
- 18. Chemical equilibria. LeChatelier's principle. Protolytic reactions I. Ionization of water. The pH scale. - Dr. Lóránd Tamás
- 19. Protolytic reactions II. Acid-base concepts. Acid-base equilibria. - Dr. Lóránd Tamás
- 20. Protolytic reactions II. Acid-base concepts. Acid-base equilibria. - Dr. Lóránd Tamás
- 21. Protolytic reactions II. Acid-base concepts. Acid-base equilibria. - Dr. Lóránd Tamás
- 22. Buffers. Physiological buffer systems. Acid-base titrations. - Dr. Lóránd Tamás
- 23. Buffers. Physiological buffer systems. Acid-base titrations. - Dr. Lóránd Tamás
- 24. Buffers. Physiological buffer systems. Acid-base titrations. - Dr. Lóránd Tamás
- 25. Heterogeneous equilibria. Thermodynamics and equilibrium. - Dr. Lóránd Tamás
- 26. Heterogeneous equilibria. Thermodynamics and equilibrium. - Dr. Lóránd Tamás
- 27. Heterogeneous equilibria. Thermodynamics and equilibrium. - Dr. Lóránd Tamás
- 28. Colligative properties. Colloids. - Dr. Perjési Pál
- 29. Colligative properties. Colloids. - Dr. Perjési Pál
- 30. Colligative properties. Colloids. - Dr. Perjési Pál
- 31. Thermochemistry. Basic thermodynamics. - Dr. Perjési Pál
- 32. Thermochemistry. Basic thermodynamics. - Dr. Perjési Pál
- 33. Thermochemistry. Basic thermodynamics. - Dr. Perjési Pál
- 34. Electrochemistry I. - Dr. Perjési Pál
- 35. Electrochemistry I. - Dr. Perjési Pál
- 36. Electrochemistry I. - Dr. Perjési Pál
- 37. Electrochemistry II. - Dr. Perjési Pál
- 38. Electrochemistry II. - Dr. Perjési Pál
- 39. Electrochemistry II. - Dr. Perjési Pál
- 40. Complex ions and coordination compounds I. Structure and isomerism. - Dr. Perjési Pál
- 41. Complex ions and coordination compounds I. Structure and isomerism. - Dr. Perjési Pál
- 42. Complex ions and coordination compounds I. Structure and isomerism. - Dr. Perjési Pál
Praktika
Seminare
- 1. The periodic table. Periodic properties.
- 2. The gaseous state. Kinetic theory of gases. Thermodynamic parameters, state functions.
- 3. Basics of thermodynamics. Internal energy and enthalpy. Entropy.
- 4. Chemical kinetics. Rate of reactions and reaction order. Temperature dependence of the reaction rate.
- 5. Homogeneous and heterogeneous chemical equilibria. Equilibrium constant. Le Chateleir principle.
- 6. Free energy change of chemical reactions. Thermodynamic requirements of spontaneous chemical reactions.
- 7. Conductivity of electrolytes. Strong and weak electrolytes.
- 8. Acid-base theories. (Arrhenius, Bronsted-Lowry, Lewis, Pearson)
- 9. Formation and stability of complexes.
- 10. pH of aqueous solutions I. Hydrolysis of salts. The hydrolysis constant.
- 11. pH of aqueous solutions II. Buffers. Buffer capacity.
- 12. Galvanic cells. Electrode potential. Electrodes of first and second kind.
- 13. Redox potential. Thermodynamic requirements of spontaneous redox reactions.
- 14. Electrolysis. Decomposition voltage. Polarization.
Materialien zum Aneignen des Lehrstoffes
Obligatorische Literatur
Ebbing D.D., Gammon S.D.: General Chemistry, Houghton Miffilin Co., Boston, 2009
Vom Institut veröffentlichter Lehrstoff
Almási A., Kuzma M., Perjési P.: General and Inorganic Chemistry - Laboratory Techniques and Practices, electronic educational material, University of Pécs, 2014
Skript
Empfohlene Literatur
en.wikibooks.org/wiki/General_Chemistry
Voraussetzung zum Absolvieren des Semesters
Acknowledgment of the course is in accord with the Code of Studies and Examinations. Participation in both the lectures and the seminars is obligatory. Maximum three absences can be accepted both from the lectures and the practices. Two compulsory midterm tests (on the topics of the lectures and the practices) will be written during the semester on the 7th and the 12th weeks. One of the test results should be above 60%, and the average of the tests should be above 50%.
Semesteranforderungen
There is no opportunity to make up missed tests.
Möglichkeiten zur Nachholung der Fehlzeiten
There is no opportunity to make up missed classes (lectures and seminars).
Prüfungsfragen
Written test covering the topics of the lectures and the seminars. The result of the first part of the written exam (Minimum Written Test) should be at least 80%. In the case of the third exam, the written exam is evaluated regardless of the result of the Minimum Written Test. The list of the possible questions of the Minimum Written Test is announced on the Neptun system. The result of the written exam must be above 60%. The final grade is based on the results of the midterm tests and the written exam. Maximum contribution of the results of the midterm tests to the total score of the written exam is 25%. Participation in the first exam is compulsory. The result of the written exam must be above 60%. The final grade is based on the results of the midterm tests and the written test. Maximum contribution of the results of the midterm tests to the total score of the written test can be 25%.
Prüfer
- Dr. Almási Attila
- Dr. Kulcsár Győző Kornél
- Dr. Lóránd Tamás
- Dr. Perjési Pál
Praktika, Seminarleiter/innen
- Dr. Almási Attila
- Dr. Kulcsár Győző Kornél
- Dr. Lóránd Tamás
- Dr. Perjési Pál