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| CHIM0275-3 | Physical chemistry I
- Thermodynamics and electrochemistry
- Introduction to spectroscopy
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| Duration : | Thermodynamics and electrochemistry : 40h Th, 30h Pr, 25h QA Sess.
Introduction to spectroscopy : 20h Th, 15h QA Sess.
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| Number of credits : |
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| Lecturer : | Thermodynamics and electrochemistry : Edwin De Pauw
Introduction to spectroscopy : Bernard Leyh
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Language(s) of instruction :
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| French language |
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Course contents :
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| Thermodynamics and electrochemistry
1. Classical Thermodynamics, including microscopic description
Degrees of freedom
Molar heat components
The Boltzmann law
The chemical potential and the equilibrium
2. Transformation at equilibrium
The moderation theorem
The variance phase diagrams of pure compounds
The variance phase diagrams of binary and ternary mixtures (distillation, eutectic, peritectic, solubility...)
Colligative properties
3. Electrochemistry
Potentiometry
Redox reactions
Thermodynamics of electrode reactions (Nernst equation)
Electrode potential
Debye-Huckel law of electrolytes
Classification of the electrodes
Conductometry
Electric conduction in solution (ohm law in solution)
Independent migration of ions
Strong and Weak electrolytes
Hittorf numbers
Batteries
Electrochemical titration methods
 | | Thermodynamics and electrochemistry |
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| Thermodynamics and electrochemistry
1. Classical Thermodynamics, including microscopic description
Degrees of freedom
Molar heat components
The Boltzmann law
The chemical potential and the equilibrium
2. Transformation at equilibrium
The moderation theorem
The variance phase diagrams of pure compounds
The variance phase diagrams of binary and ternary mixtures (distillation, eutectic, peritectic, solubility...)
Colligative properties
3. Electrochemistry
Potentiometry
Redox reactions
Thermodynamics of electrode reactions (Nernst equation)
Electrode potentialDebye-Huckel law of electrolytes
Classification of the electrodes
Conductometry
Electric conduction in solution (ohm law in solution)
Independent migration of ions
Strong and Weak electrolytes Hittorf numbers
Batteries
Electrochemical titration methods |
| | Introduction to spectroscopy |
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| Introduction to quantum mechanics and to molecular spectroscopy: (i) The birth of quantum mechanics; (ii) The Schrödinger equation applied to the particle-in-a-box model (iii) The postulates of quantum mechanics; (iv) The tunnel effect: principle and applications; (v) The quantum theory of angular momentum; (vi) Nuclear magnetic resonance spectroscopy (NMR); (vii) Infrared vibrational spectroscopy. This basic course aims at helping the student to apply spectroscopy to organic, inorganic and analytical problems. |
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Learning outcomes of the course :
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| Thermodynamics and electrochemistry
In the second course on Physical Chemistry, the topics introduced during the first course (General Chemistry) are described in details to open the way to the generalization of physico-chemical concepts and their applications.
The topics of the course are grouped in 5 chapters.
Chapter 1 is intended to give solid basis in classical thermodynamics starting from an extended introduction to its microscopic description. These concepts are applied to equilibrium situations in chapter 2. Thermodynamic and kinectic aspects of electrochemistry are presented in chapter 3. 10 hours are devoted to thermodynamics under extreme conditions.
| | Thermodynamics and electrochemistry |
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| Thermodynamics and electrochemistry
In the course on Physical Chemistry, the topics introduced during the course on General Chemistry are described in details to open the way to the generalization of physico-chemical concepts and their applications.
The topics of the course are grouped in 3 chapters.
Chapter 1 is intended to give solid basis in classical thermodynamics starting from an extended introduction to its microscopic description. These concepts are applied to equilibrium situations in chapter 2, including examples on binary and ternary mixtures. Thermodynamic and kinetic aspects of electrochemistry are presented in chapter 3. |
| | Introduction to spectroscopy |
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| At the end of the course, the student is expected to be able
(i) to explain the basic quantum mechanical principles which govern spectroscopic experiments
(ii) to infer, in cases of moderate difficulty, as much information as possible from experimental spectroscopic data. |
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Prerequisites and co-requisites/ Recommended optional programme components :
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| Thermodynamics and electrochemistry
Good knowledge of general chemistry (first year)
| | Thermodynamics and electrochemistry |
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| General Chemistry entry level |
| | Introduction to spectroscopy |
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| Freshman chemistry and physics courses. |
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Planned learning activities and teaching methods :
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| | Thermodynamics and electrochemistry |
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| 40 hours of theory 25 hours of problems solving 30 hours of practical work (laboratory). Upon request revisions at the end of the program |
| | Introduction to spectroscopy |
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| There is no laboratory work foreseen for this course. Problem-solving classes are organized. Problems of both theoretical and numerical nature will be solved. |
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Mode of delivery (face-to-face ; distance-learning) :
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| Thermodynamics and electrochemistry
40 hours of theory
25 hours of problems solving
30 hours of practical work (laboratory)
upon request revisions at the end of the program
| | Thermodynamics and electrochemistry |
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| Face-to-face teaching
The student must be present at the laboratory training |
| | Introduction to spectroscopy |
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| 10 two-hour lectures during the second quadrimester
A few problem-solving classes (alltogether 15 hours) |
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Recommended or required readings :
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| Thermodynamics and electrochemistry
Chimie générale II , E . De Pauw
Physical Chemistry, P. Atkins
| | Thermodynamics and electrochemistry |
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| Syllabus
E-documents
Physical Chemistry, P. Atkins |
| | Introduction to spectroscopy |
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| Lecture notes. Extensive use of the blackboard is made during the lectures. |
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Assessment methods and criteria :
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| Thermodynamics and electrochemistry
The final evaluation concerns all the parts of the course (theory, problems, laboratory)
| | Thermodynamics and electrochemistry |
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| The final evaluation concerns all the parts of the course (theory: written and oral examination, problems: written examination and regular written interrogations, laboratory) |
| | Introduction to spectroscopy |
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| A test on the exercices is organised at the end of the course. Students who succeed in this test are not required to pass the written exam mentioned below.
Written (theoretical and numerical problems) and oral examinations.
To obtain a global grade better than, or equal to, 8/20 for the CHIM0275-3 course, it is required to reach at least 8/20 for both parts of the course separately (CHIM0275-B-a and CHIM0275-C-a). |
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Organizational remarks :
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| | Thermodynamics and electrochemistry |
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| See official agenda |
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Contacts :
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| Thermodynamics and electrochemistry
Professor : De Pauw Edwin
e.depauw@ulg.ac.be
tel: 3663415
Secretary : Danielle Salvé
d.salve@ulg.ac.be
tel: 3663414
Assistant : Pierre Colson
Pierre.Colson@ulg.ac.be
tel: 3663435
| | Thermodynamics and electrochemistry |
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| e.depauw@ulg.ac.be |
| | Introduction to spectroscopy |
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| Bernard Leyh, Molecular Dynamics Laboratory, Department of Chemistry, Building B6c, Office R77, Lab S48 - Phone : 04/3663425 - E-mail : Bernard.Leyh@ulg.ac.be
(dbalbeur@ulg.ac.be) |
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