Uw huidige browser heeft updates nodig. Zolang u niet update zullen bepaalde functionaliteiten op de website niet beschikbaar zijn.
Let op: het geselecteerde rooster heeft overlappende bijeenkomsten.
Volgens onze gegevens heb je nog geen vakken behaald.
Je planning is nog niet opgeslagen
Let op! Uw planning heeft vakken in dezelfde periode met overlappend timeslot
Physical Chemistry
Cursusdoel
- appreciate how the foundations of chemistry are based on physical laws and mathematical methods.
- appreciate and apply the laws of thermodynamics, thermodynamic energies and entropy and relate them to the statistical description of matter.
- work with the physico-chemical treatment of matter (simple gases, liquids and mixtures, etc.) including its relation to phase transitions.
- appreciate the role of quantum mechanics in the description of the properties of atoms and molecules.
- apply the principles of quantum mechanics to the basic types of motion (translation, rotation, and vibration) and describe the dynamical properties of microscopic systems.
- analyze and interpret simple molecular spectra and infer molecular properties such as bond strengths, lengths, and angles, and molecular orbital energies.
- address examples of complex systems (polymers, colloids, membranes, biological macromolecules).
- identify and understand applications in different fields (energy, biological systems, art, materials science).
- do actual calculations by applying and manipulating appropriate equations and empirical data.
- work with scientific sources (doing literature research, selecting, and processing scientific information) on a specific topic from physical chemistry.
- Written examination 1 (weight 25%): this tests your knowledge of, and ability to apply the topics and concepts covered in the first part of the course (course goals 1-3).
- Written examination 2 (weight 35%): this tests your knowledge of, and ability to apply the topics and concepts covered in the second and third parts of the course (course goals 4-8).
- Essay and presentation (weight 20%): this tests your ability to collect information about, internalize, apply, and explain specific experimental techniques or theoretical concepts from physical chemistry, as well as your presentation skills and ability to transfer the knowledge acquired orally and in writing (course goals 1–8, 10).
- Homework exercises (weight 10%): this tests your ability to apply the theoretical concepts discussed in the course by solving specific exercises and problems (topics 1–9).
- Course participation: (weight 10%): this tests your preparation and engagement with the course, as well as the ability to elaborate on the theoretical concepts discussed (topics 1–9).
Vakinhoudelijk
The first part of the course explores the classical basis of the laws of thermodynamics and the applications of these laws to describe physical and chemical transformations (e.g., phase transitions, ideal solutions, mixtures, and electrolyte solutions). The link between bulk (macroscopic) and microscopic properties of matter is then discussed in the context of statistical thermodynamics, i.e., how the thermal motion of molecules and supramolecular particles leads to the (re)distribution of energy in these systems.
In the second part of the course, we start by revising and expanding the principles of quantum theory and then build on these principles to explore the main features of atomic and molecular spectroscopy methods. We will examine applied examples of rotational, vibrational, and electronic spectra, and show how the information obtained in this way can provide insight into molecular structure and reactivity. We will also discuss the fates of electronic excited states and examine some important examples of photochemical process (e.g., photosynthesis, human formation of vitamin D, bioluminescence).
In daily life, one often encounters more complicated forms of matter involving larger molecules (polymers) or particles and/or larger structures such as emulsions or membranes formed by soap-like molecules. The final part of the course will discuss the physical chemistry of these systems, bringing together the concepts discussed throughout the course.
Format
The course covers 200 hours. Topics are introduced by the teacher, but also require self-study. Part of the class time is available for working on selected problems related to the contents of the lectures. Solutions to selected homework problems must be handed in regularly (4 moments during the course). Students will work individually on an essay and presentation on a selected topic and present it to their colleagues and the teacher.
Werkvormen
Toetsing
Class participation
Verplicht | Weging 10% | ECTS 0,75
Homework
Verplicht | Weging 10% | ECTS 0,75
Essay and presentation
Verplicht | Weging 20% | ECTS 1,5
*midterm FEEDBACK*
Niet verplicht
Written examination 1
Verplicht | Weging 25% | ECTS 1,88
Written examination 2
Verplicht | Weging 35% | ECTS 2,63
Ingangseisen en voorkennis
Ingangseisen
Er moet voldaan zijn aan de cursussen:
En er moet voldaan zijn aan minimaal één van de cursussen:
- [UCSCIPHY12] Relativistic and Classical Physics
- [UCSCIPHY13] Introduction to Wave Phenomena in Nature
- [UCSCIPHY14] Introduction to Wave Phenomena in Nature - enhanced
Voorkennis
Er is geen informatie over benodigde voorkennis bekend.
Voertalen
- Engels
Cursusmomenten
Gerelateerde studies
Tentamens
Er is geen tentamenrooster beschikbaar voor deze cursus
Verplicht materiaal
Materiaal | Omschrijving |
---|---|
BOEK | Atkins, P.W., De Paula, J. (2017), Elements of Physical Chemistry (7th ed.), Oxford University Press, Oxford. ISBN: 9780198727873 |
Aanbevolen materiaal
Er is geen informatie over de aanbevolen literatuur bekend
Coördinator
dr. C.A. van Walree | c.a.vanwalree@uu.nl |
Docenten
dr. M. Barroso | m.barroso@uu.nl |
Inschrijving
Naar OSIRIS-inschrijvingen
Permanente link naar de cursuspagina
Laat in de Cursus-Catalogus zien