- Docente: Alberto Credi
- Credits: 6
- SSD: CHIM/03
- Language: Italian
- Teaching Mode: Traditional lectures
- Campus: Bologna
- Corso: First cycle degree programme (L) in Astronomy (cod. 8004)
Learning outcomes
The objective of the course is to provide the essential elements
relative to the composition and behaviour of the various substances
that constitute the Universe. At the same time, the course is
intended to give the necessary information for a critical analysis
on the following topics:
- the composition of the material objects in the surrounding world;
- the dependence of the macroscopic properties of substances on
their microscopic composition and structure;
- the ability of substances to combine together, or to decompose, giving rise to other substances.
Course contents
The course is divided in three parts, corresponding to the
following subjects:
1) characterization of the fundamental components of substances (atoms);
2) study of the chemical properties of atoms, i.e., of their ability to aggregate according to well established rules, giving rise to a huge variety of substances (chemical species);
3) study of the transformations of substances, either spontaneous or man-made, and of the conditions in which these transformations can take place (chemical reactions).
PART I: macroscopic and microscopic structure of matter
The atomic structure of matter. Atoms. Chemical formulas and molecular weight. Mole. Qualitative and quantitative meaning of chemical formulas.
The electronic structure of atoms. Bohr's atomic model. Quantization of energy. Dual nature of the electron and Heisenberg's principle. Wave theory, quantum numbers and atomic orbitals. Energy levels for atomic hydrogen. Atomic orbitals in atoms with many electrons. Pauli's principle and Hund's rule. Electronic configuration of atoms (aufbau) and periodic classification of chemical elements (Periodic Table). Laboratory experiment on atomic spectroscopy.
Periodic change of the physical properties of atoms. Atomic size, ionization energy and electron affinity.
PART II: the chemical bond
The chemical bondand the energy of the system. Bond energy. Classification of chemical bonds.
The covalent bond. Valence bond theory. Polarity of covalent bonds, electronegativity. Stoichiometry of covalent compounds. Molecular geometry and VSEPR model. Polar and apolar molecules. Laboratory exercise on molecular geometry and polarity. Molecular orbital theory. Energy diagram of the molecular orbitals and electronic configuration of some simple biatomic molecules.
The chemical bond in the solid state. Ionic bond. Structure and properties of ionic compounds. Metallic bond. Short account on band theory for solids. Conductors, insulators and semiconductors.
Attractive forces between molecules in condensed phases. Van der Waals interactions. Hydrogen bonds. Factors determining the aggregation state of a substance.
Periodic behaviour of bond properties. Relationship between bond types and atom position in the Periodic Table. Prediction of the bond nature.
Chemical properties of the elements relative to their position in the Periodic Table. Periodic chemical properties. Properties of the compounds between the various elements and oxygen (oxides, hydroxides, oxoacids) or hydrogen (hydrides). Salts. Solutions: properties and composition. Gaseous solutions. Solubility. Electrolytic solutions.
PART III. Chemical reactions
Chemical equations. Energy involved in chemical reactions: internal energy and entalpy. Spontaneity of a chemical process: entropy and free energy.
Chemical equilibria. Homogeneous and heterogeneous equilibria. Equilibrium constant and its temperature dependence. Predictions on the evolution of a chemical system. Principle of Le Chatelier. Choice of the best reaction conditions.
Chemical kinetics. Rate of a chemical reaction. Factors affecting the reaction rate. Rate constants, order of reactions and lifetimes. Reaction mechanism and elementary steps. Activation energy. Catalysis.
Thermodynamic and kinetic aspects of a reactive chemical system. Laboratory experiments on the reactivity of some chemical species.
Readings/Bibliography
Textbooks:
A. M. Manotti Lanfredi, A. Tiripicchio, Fondamenti di Chimica, C.E.A, Milano, 2006.
I. Bertini, C. Luchinat, F. Mani, Chimica, C.E.A., Milano, 2004.
L. Moggi, M. Venturi, Chimica Generale ed Inorganica (2° ed.), Corso Ed., Ferrara, 2002.
Further reading:
M. Munowitz, Chimica, Zanichelli, Bologna, 2003
P. Chiorboli, Fondamenti di Chimica, UTET, Bologna
P. Atkins, L. Jones, Chimica Generale, Zanichelli, Bologna, 1998
Teaching methods
The course is composed mainly of classroom lectures with the use of transparencies. Other classroom activities (problem solving) and a few laboratory experiments (8 hours of overall activity in the lab) are carried out. Subjects of high impact (e.g., under an applicative point of view), related to the topics treated in the course, are presented if time is available.
Assessment methods
The exam is composed of a written test that, if positively
evaluated, gives access to the oral exam, which ultimately
determines the mark. The student is asked at least three questions.
Brief reports on the experiments performed in the laboratory are
also required. Attending the laboratory activities is not
compulsory; however, in case of unjustified absence in the
laboratory dates and/or the lab reports are not delivered at least
7 days before the oral exam, the final mark will be decreased by 3
points.
For logistic reasons, a registration for the participation to the written test is necessary. Registration has to be made through the AlmaEsami web site. Should this not be possible, please register either by e-mail (alberto.credi@unibo.it) or by phone (051-2099540).
Teaching tools
The transparencies used in the lectures can be downloaded from the Internet (UniBo > Alberto Credi > Insegnamenti > Chimica > Materiale didattico). The text of problems and exercises – some with solution – for training to the written test are available in the same site.
Links to further information
Office hours
See the website of Alberto Credi