GENERAL AND INORGANIC CHEMISTRY
- Overview
- Assessment methods
- Learning objectives
- Contents
- Full programme
- Bibliography
- Delivery method
- Teaching methods
- Contacts/Info
The course begins with elementary notions and does require previous knowledge of chemistry from high school.
Basic knowledges of mathematics and physics, provided during the years of high school, are required.
Six exam sessions are scheduled, on the dates set by the University calendar; the examination consists in a written test of 2hrs with the resolution of eight problems pertinent to: theory, stoichiometry and redox, molecular geometries, thermodynamics and chemical equilibrium, colligative properties, acid-base reactions and solubility, electrochemical cells. The student has passed the exam, only if the written test results are ≥ 18/30. The written test consists in a resolution and in a logical exposition of selected topics among the most important ones of the course.
SUBJECT GOALS
Introduction and training goals
Teaching this course means giving the bases for understanding the macroscopic properties of matter, starting from the structure of atoms and molecules, and their properties. The course develops the criteria to understand the ability of a substance to react, or to break and to form bonds, and the corresponding energy exchanges, in relation with possible applications and with the behaviour of materials. The exercises will examine thoroughly, not only numerically, the aspects treated in class.
LEARNING OUTCOMES
Knowledge and understanding
-acquisition of competences and tools suitable for the communication of the collection, the elaboration and the presentation of the data.
-acquisition of abilities suitable for the development and examination of further skills for a strong learning of basic notions, for a following autonomous acquisition of higher knowledge, and for continuous updating.
Applying knowledge and understanding (Skills and knowhow)
- acquiring the fundamental elements of general chemistry and inorganic reactivity;
- knowing the main chemical and physical factors that influence chemical reactions;
-developing the ability to describe analytically, to simulate, to analyze and to solve problems of physical-biological interest as well;
- showing the ability of extracting and synthesizing the relevant information;
- showing ability of communicating in an effective way and with the correct terminology, both orally and in writing.
Lectures (5 CFU-40 hrs in classroom)
1) The atomic nature of matter (1,375 Credits–11 hrs)
Matter: atoms and molecules, elements and compounds, the mole and Avogadro's constant.
Types of physical chemistry reactions. Atomic theory of matter, chemical periodicity and overview of quantum mechanics. Electronic structure and atoms properties. The periodic table and dependence of atomic properties on the electronic structure.
Chemical bonding. Electronegativity according to Pauling and molecular polarity.
Intermolecular attractions and the properties of liquids and solids.
Inorganic chemical nomenclature.
2) Thermochemistry and thermodynamics (0,750 Credits–6 hrs)
The first law of thermodynamics. The second law and the third law of thermodynamics.
3) Chemical equilibria (0,625 Credits–5 hrs)
Chemical equilibrium and equilibrium constants.
4) Liquids and solutions (0,625 Credits–5 hrs)
Solutions properties: phase equilibria and colligative properties of solutions.
5) Chemical transformations in water solutions (1,5 Credits–12 hrs)
Acids and bases: Arrhenius, Brönsted and Lewis definitions. Water and the pH scale: strong acid and base, weak acids and bases.
Redox reactions and electrochemistry.
6) Inorganic chemistry (0,250 Credits–2 hrs)
Tutorials (1 CFU–12 hrs in classroom)
Lectures (5 CFU-40 hrs in classroom)
1)The atomic nature of matter (1,375 Credits–11 hrs)
Matter: atoms and molecules, elements and compounds, the mole and Avogadro's constant.
Types of physical chemistry reactions.
Atomic theory of matter, chemical periodicity and overview of quantum mechanics: photoelectric effect, De Broglie equation, Heinseberg uncertainly principle, Schrödinger equation. Quantum numbers and atomic orbitals. Electronic structure and atoms properties: Pauli principle, Hund rule and “aufbau prinzip”. The periodic table and dependence of atomic properties on the electronic structure.
Chemical bonding: structure and properties of the substances. Ionic bond. Covalent bond and molecular geometry, VSEPR theory. Hybrid orbitals and steric number. Electronegativity according to Pauling and molecular polarity.
Intermolecular attractions and the properties of liquids and solids. Hydrogen bond. Gaseous state and condensed phase. Metallic solids, ionic solids, covalent solids and molecular solids.
Inorganic chemical nomenclature.
2)Thermochemistry and thermodynamics (0,750 Credits–6 hrs)
The first law of thermodynamics. State function enthalpy (H) and Hess law. Enthalpy of formation, reaction and combustion. The second law and the third law of thermodynamics: state function entropy (S) and state function Gibbs free energy (G).
3)Chemical equilibria (0,625 Credits–5 hrs)
Chemical equilibrium and equilibrium constants: homogenous and heterogeneous equilibria. Le Châtelier principle and chemical equilibria.
4)Liquids and solutions (0,625 Credits–5 hrs)
Solutions properties: ideal solutions, Raoult law and Henry law. Phase equilibria. Colligative properties of solutions. Phase diagrams.
5)Chemical transformations in water solutions (1,5 Credits–12 hrs)
Acids and bases: Arrhenius, Brönsted and Lewis definitions. Water and the pH scale: strong acid and base, weak acids and bases. Buffer solutions. Dissolution and precipitation equilibria.
Redox reactions and electrochemistry: balancing redox equations, using standard reduction potentials, Nernst equation, free energy and cell voltage. Electrolysis and Faraday law.
6)Inorganic chemistry (0,250 Credits–2 hrs)
An overview of inorganic chemistry topics that relate to the biochemical field.
Tutorials (1 CFU–12 hrs in classroom)
Atomic and molecular mass, isotopes. Mole and number of molecules. Chemical reactions and equations. Ideal gases and mixtures gases. Concentrations and stoichiometry of the reactions in aqueous solutions. Atomic and molecular structure, chemical bond. Intermolecular forces: solids, liquids, gases. Energy and energy balances, thermodynamics and chemical equilibrium. Colligative properties of solutions. Electrolyte solutions: salts, acids, bases and pH. Spontaneity of redox reactions. Electrochemical and electrolytic cells.
Theory: Brown, Lemay, Bursten, Murphy, Woodward “Fondamenti di Chimica” Ed. EdiSES
J. C. Kotz, P. M. Treichel, J. R. Townsend, D. A. Treichel "Chimica" Ed. EdiSES
Stoichiometry: D'Arrigo, Famulari, Gambarotti, Scotti “Chimica: Esercizi e Casi Pratici” III Edizione/2017 Ed. EdiSES
Sets of university lectures, texts of examination with resolution and exercises are available on the site e-learning.
The course consists of lectures (5 CFU) and classroom exercises (1 CFU). In the lectures and tutorials, the treatment of the topics is also carried out with the help of presentations shown in the classroom, complemented by the screening of educational films
OFFICE HOURS AND MAIL ADDRESS
At the end of every lesson or upon appointment via e-mail, using the official student’s address: @studenti.uninsubria.it
The e-mail address of professor is massimo.scotti@uninsubria.it or massimo.scotti@polimi.it