Atoms, ions and molecules.
The electronic structure of atoms and the chemical periodicity.
Chemical bonding and molecular structure.
Intermolecular forces and states of matter.
The gaseous state.
Colligative properties.
Chemical equations and reaction stoichiometry.
Chemical thermodynamics.
Chemical equilibrium.
Electrochemistry.
Chemical kinetics.
Course Content - Last names E-N
Atomic structure. Electronic structure of the atom. Periodic table. Chemical bonds and their general characteristics. Intermolecular forces and states of matter. Laws of Gases. Thermochemistry. Chemical equilibrium. Chemical reactions. Colligative properties. Electrochemistry: electrochemical processes; batteries and electrode potentials; the phenomenon of corrosion; electrolysis. Chemical kinetics.
Course Content - Last names O-Z
Atomic structure. Electronic structure of the atom. Periodic table. Chemical bonds and their general characteristics. Intermolecular forces and states of matter. Laws of Gases. Thermochemistry. Chemical equilibrium. Chemical reactions. Colligative properties. Electrochemistry: electrochemical processes; batteries and electrode potentials; the phenomenon of corrosion; electrolysis. Chemical kinetics.
- Dapporto, Paoli, Rossi, Lezioni di Chimica, ed. Progetto Leonardo
-Chang, Overly, Fondamenti di chimica generale, McGraw-Hill
-Bertini, Luchinat, Mani, Stechiometria, ed. Casa Editrice Ambrosiana
- Atkins, Jones, Fondamenti di chimica generale, Zanichelli
- Atkins, Jones, Fondamenti di chimica generale, Zanichelli
- McQuarrie, Rock, Gallogly, Principi di Chimica, ed. Zanichelli
-Shultz, Chimica Generale, Ed. Zanichelli
-Silberberg, Chimica, ed. McGraw-Hill
-Ugozzoli, Come risolvere i problemi di chimica, Ed. Zanichelli
Learning Objectives - Last names A-D
The course aims at providing students with the basic knowledge of chemistry essential to form a scientific knowledge to which to add the specific characteristics of the course of study. In particular, the course topics are selected in such a way as to enable students to face, understand and evaluate the chemical, thermodynamic, kinetic and catalytic aspects related to chemical processes and their optimal conduction.
Students will acquire:
cc2: Knowledge and understanding of the relevant laws of chemistry and some laws of physics (thermodynamics) in the field of industrial engineering and understanding of the role of these laws in the formulation of representative models of tangible reality.
Student will be able to:
ca2: Applying knowledge and understanding related to the chemical field to solve mono-disciplinary problems of chemistry as a basis for mechanical engineering problems.
ct3: Development of an adequate expression and technical discussion of own arguments.
ct7: To respect commitments and deadlines.
Learning Objectives - Last names E-N
The course aims at providing students with the basic knowledge of chemistry essential to form a scientific knowledge to which to add the specific characteristics of the course of study. In particular, the course topics are selected in such a way as to enable students to face, understand and evaluate the chemical, thermodynamic, kinetic and catalytic aspects related to chemical processes and their optimal conduction.
Students will be acquire:
cc2: Knowledge and understanding of the relevant laws of chemistry and some laws of physics (thermodynamics) in the field of industrial engineering and the understanding of the role of these laws in the formulation of representative models of tangible reality
students will be able to:
ca2: Applying knowledge and understanding related to the chemical field to solve mono-disciplinary problems of chemistry as a basic for mechanical engineering problems.
Ct3: development of an adequate expression and technical discussion of own arguments
Ct7: to respect commitments and deadlines
Learning Objectives - Last names O-Z
The course aims at providing students with the basic knowledge of chemistry essential to form a scientific knowledge to which to add the specific characteristics of the course of study. In particular, the course topics are selected in such a way as to enable students to face, understand and evaluate the chemical, thermodynamic, kinetic and catalytic aspects related to chemical processes and their optimal conduction.
Students will be acquire:
cc2: Knowledge and understanding of the relevant laws of chemistry and some laws of physics (thermodynamics) in the field of industrial engineering and the understanding of the role of these laws in the formulation of representative models of tangible reality
students will be able to:
ca2: Applying knowledge and understanding related to the chemical field to solve mono-disciplinary problems of chemistry as a basic for mechanical engineering problems.
Ct3: development of an adequate expression and technical discussion of own arguments
Ct7: to respect commitments and deadlines
Prerequisites - Last names A-D
Not required
Prerequisites - Last names E-N
Prerequisites are not requested
Prerequisites - Last names O-Z
Prerequisites are not requested
Teaching Methods - Last names A-D
Teaching is delivered in a mixed-mode, remotely and face-to-face. Approximately 20% of the total teaching hours will be devoted to exercises designed to prepare students to take the final exam.
Teaching Methods - Last names E-N
The course includes lectures (which will occupy approximately 70-80% of the total teaching hours) and exercises designed to prepare students to take the final exam.
Teaching Methods - Last names O-Z
The course includes lectures (which will occupy approximately 70-80% of the total teaching hours) and exercises designed to prepare students to take the final exam.
Further information - Last names A-D
Testing texts will be provided by the teacher (available on the Moodle online platform).
Further information - Last names E-N
Testing texts and teaching material related to particular topics will be provided by the teacher.
Further information - Last names O-Z
Testing texts and teaching material related to particular topics will be provided by the teacher.
Type of Assessment - Last names A-D
The student evaluation includes a written test followed by an oral exam. In open-ended questions the student must demonstrate, in addition to a good knowledge of the topics covered (CC2 competence), to have sufficient exposure skills and to possess a specialized lexicon at least sufficient. In the exercises, the student will have to demonstrate a good ability to apply the acquired knowledge to solve problems in the chemical field (CA2 capacity). In the oral exam her/ his ability to organize her/his knowledge in the chemical field will be evaluated.
Type of Assessment - Last names E-N
The student evaluation includes a written test and an oral exam. The student must demonstrate, in addition to a good knowledge of the topics covered (CC2 competence), also to have sufficient exposure skills and to possess a specialized lexicon at least sufficient. In the exercises, the student will have to demonstrate a good ability to apply the acquired knowledge to solve problems in the chemical field (CA2 capacity). In the oral test her/ his ability to organize her/his knowledge in the chemical field will be evaluated. This capacity must at least be sufficient
Type of Assessment - Last names O-Z
The student evaluation includes a written test and an oral exam. The student must demonstrate, in addition to a good knowledge of the topics covered (CC2 competence), also to have sufficient exposure skills and to possess a specialized lexicon at least sufficient. In the exercises, the student will have to demonstrate a good ability to apply the acquired knowledge to solve problems in the chemical field (CA2 capacity). In the oral test her/ his ability to organize her/his knowledge in the chemical field will be evaluated. This capacity must at least be sufficient
Course program - Last names A-D
Atomic structure of matter. Atoms, ions and molecules: the atomic model of matter; the subatomic particles; isotopes, atomic weight, molecular weight, mole.
Electronic structure of the atom. The Heisenberg uncertainty principle; electromagnetic radiation; light-matter interaction: absorption and emission spectra; the wave-particle duality and De Broglie's relationship; the Schrodinger equation; quantum numbers; atomic orbitals (s, p, d, f). Polyelectronic atoms; the quantum number of spin; the screen effect; energy flow of the orbitals as a function of Z; rules for filling the orbitals (minimum energy, Pauli, Hund).
Periodic system. Periodic table of the elements; periodic quantities (ionization energy, electronic affinity, atomic radius, electronegativity).
Chemical bonds. Introduction to chemical bonding. The covalent bond; hybridization and geometry of molecules; VSEPR theory. Pure and polar covalent bonds; dipole moment; polar and apolar molecules; the ionic bond. General characteristics of metals and metallic bonding.
Intermolecular forces and solid state. The hydrogen bond. Intermolecular forces and states of aggregation of matter. Types of solids: metallic, ionic, covalent and molecular. Main properties of the different types of solids.
Gaseous state. gas law equations. State diagram. Colligative properties.
Elements of thermodynamics. Thermochemistry. Chemical equilibrium. Law of mass action. Le Chatelier's principle. Spontaneity of a transformation.
Chemical reactions. Reactions in solution (molarity and pH). Oxidation-reduction and combustion reactions. Oxidation number, balancing redox reactions.
Electrochemistry. Galvanic cells; the Nernst equation; spontaneity and displacement of redox reactions; oxidation-reduction reactions of water; electrolysis of molten salts and in aqueous solution; Faraday laws. The phenomenon of corrosion. Strategies for corrosion protection.
Chemical kinetics.
Course program - Last names E-N
- Atomic structure of matter. Atoms, ions and molecules: the atomic model of matter; the subatomic particles; atomic weight, molecular weight, isotopes, mole.
-Electronic structure of the atom. The Heisenberg uncertainty principle; electromagnetic radiation; light-matter interaction: absorption and emission spectra; the wave-particle duality and De Broglie's relationship; wave mechanics; the Schrodinger equation; eigenfunctions and eigenvalues; quantum numbers; the wave function in polar coordinates, the physical meaning of the wave function. orbitals s, p, d, f; Polyelectronic atoms; the quantum number of spin; the screen effect; energy flow of the orbitals as a function of Z; rules for filling the orbitals (minimum energy, Pauli, Hund).
- Periodic system. Periodic table of the elements; periodic quantities: ionization energy, electronic affinity, atomic radius.
- Chemical bonds. Introduction to chemical bonding. The covalent bond; hybridization and geometry of molecules; VSEPR theory, expansion of the octet; resonance; formal charge. Structural formulas; Electronegativity; pure and polar covalent bonds; dipole moment; polar and apolar molecules; the ionic bond. General characteristics of metals. Intrinsic and extrinsic semiconductors. Covalent bond model and energy band model.
- Intermolecular forces and solid state. The hydrogen bond. Intermolecular forces and states of aggregation of matter. Types of solids: metallic, ionic, covalent and molecular. Main properties of the different types of solids. The solid state: amorphous solids and crystalline solids. Crystalline lattices and elementary cells (outline).
- Gaseous state. equation of state of perfect gases; van der Waals state equation.
- State diagram.
- Colligative properties: lowering of vapor pressure, elevation of boiling point, depression of freezing point, osmotic pressure.
-Elements of chemical thermodynamics. First principle. Thermochemistry (reaction enthalpy, Hess's law). - Chemical equilibrium. Law of mass action. Le Chatelier's principle. Criterion of spontaneity of a transformation.
- Chemical reactions. Reactions in solution (molarity and pH). Oxidation-reduction and combustion reactions. The oxidation number. Balancing of an oxidation-reduction reaction.
-Elettcrochemistry. The batteries; the Nernst equation; spontaneity and displacement of redox reactions; oxidation-reduction reactions of water; electrolysis of molten salts and in aqueous solution; Faraday laws. The phenomenon of corrosion. Strategies for corrosion protection.
- Chemical chemistry. Speed of chemical reactions; reaction order and reaction mechanisms; activation energy; catalysis.
Course program - Last names O-Z
- Atomic structure of matter. Atoms, ions and molecules: the atomic model of matter; the subatomic particles; atomic weight, molecular weight, isotopes, mole.
-Electronic structure of the atom. The Heisenberg uncertainty principle; electromagnetic radiation; light-matter interaction: absorption and emission spectra; the wave-particle duality and De Broglie's relationship; wave mechanics; the Schrodinger equation; eigenfunctions and eigenvalues; quantum numbers; the wave function in polar coordinates, the physical meaning of the wave function. orbitals s, p, d, f; Polyelectronic atoms; the quantum number of spin; the screen effect; energy flow of the orbitals as a function of Z; rules for filling the orbitals (minimum energy, Pauli, Hund).
- Periodic system. Periodic table of the elements; periodic quantities: ionization energy, electronic affinity, atomic radius.
- Chemical bonds. Introduction to chemical bonding. The covalent bond; hybridization and geometry of molecules; VSEPR theory, expansion of the octet; resonance; formal charge. Structural formulas; Electronegativity; pure and polar covalent bonds; dipole moment; polar and apolar molecules; the ionic bond. General characteristics of metals. Intrinsic and extrinsic semiconductors. Covalent bond model and energy band model.
- Intermolecular forces and solid state. The hydrogen bond. Intermolecular forces and states of aggregation of matter. Types of solids: metallic, ionic, covalent and molecular. Main properties of the different types of solids. The solid state: amorphous solids and crystalline solids. Crystalline lattices and elementary cells (outline).
- Gaseous state. equation of state of perfect gases; van der Waals state equation.
- State diagram.
- Colligative properties: lowering of vapor pressure, elevation of boiling point, depression of freezing point, osmotic pressure.
-Elements of chemical thermodynamics. First principle. Thermochemistry (reaction enthalpy, Hess's law). - Chemical equilibrium. Law of mass action. Le Chatelier's principle. Criterion of spontaneity of a transformation.
- Chemical reactions. Reactions in solution (molarity and pH). Oxidation-reduction and combustion reactions. The oxidation number. Balancing of an oxidation-reduction reaction.
-Elettcrochemistry. The batteries; the Nernst equation; spontaneity and displacement of redox reactions; oxidation-reduction reactions of water; electrolysis of molten salts and in aqueous solution; Faraday laws. The phenomenon of corrosion. Strategies for corrosion protection.
- Chemical chemistry. Speed of chemical reactions; reaction order and reaction mechanisms; activation energy; catalysis.
Sustainable Development Goals 2030 - Last names A-D
Affordable and Clean Energy
Sustainable cities and communities
Sustainable Development Goals 2030 - Last names E-N
Clean and accessible energy;
sustainable cities and communities
Sustainable Development Goals 2030 - Last names O-Z
Clean and accessible energy;
sustainable cities and communities