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.
Chemical equations and reaction stoichiometry.
Chemical thermodynamics.
Chemical equilibrium.
Electrochemistry.
Course Content - Last names E-N
atomic structure; electronic structure of atoms and periodic table. Covalent and ionic bonding; intermolecular weak interactions. The properties of gases and solids. An introduction to thermodynamics. Solutions; chemical equilibria. Reaction kinetics. Electrochemistry
Course Content - Last names O-Z
atomic structure; electronic structure of atoms and periodic table. Covalent and ionic bonding; intermolecular weak interactions. The properties of gases and solids. An introduction to thermodynamics. Solutions; chemical equilibria. Reaction kinetics. Electrochemistry
- Dapporto, Paoli, Rossi, Lezioni di Chimica, ed. Progetto Leonardo
- Fusi, Bacchi, Dei, Giorgi, Marchetti, Messori, Paoli, Punzo, Sortino, Tolazzi, CHIMICA Generale e Inorganica, ed. Idelson Gnocchi
- Atkins, Jones, Fondamenti di chimica generale, Zanichelli
- McQuarrie, Rock, Gallogly, Chimica Generale, ed. Zanichelli
-Shultz, Chimica Generale, Ed. Zanichelli
-Silberberg, Chimica, ed. McGraw-Hill
-Bertini, Luchinat, Mani, Stechiometria, ed. Casa Editrice Ambrosiana
-Ugozzoli, Come risolvere i problemi di chimica, Ed. Zanichelli
Learning Objectives - Last names A-D
The course aims to provide students with the basic knowledge of chemistry essential for understanding the relationships between microscopic structure and macroscopic properties of materials, thus contributing to form a base of basic 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:
Knowledge and understanding of the relevant laws of physics (mechanics, electromagnetism, thermodynamics) and chemistry in the field of industrial engineering and understanding of the role of these laws in the formulation of representative models of tangible reality. Knowledge and understanding of thermodynamics applied to energy systems and of fluid-dynamic phenomena as well as models capable of representing them. Knowledge of systems and machines for the production and conversion of energy, with particular reference to turbomachinery and industrial combustion equipment. Understanding the role of different energy technologies in ensuring the environmental and economic sustainability of production.
Studente will be able to:
Applying knowledge and understanding related to the physical and chemical field to solve mono-disciplinary problems of chemistry, applied chemistry, mechanics, electromagnetism and theoretical thermodynamics as a basis for mechanical engineering problems.
Learning Objectives - Last names E-N
The aim of this course is to provide the student with basic knowledge of chemistry that allows him to understand the relationships between microscopic and macroscopic properties of matter.
Learning Objectives - Last names O-Z
The aim of the course is to provide the student with the knowledge of chemistry that is essential to form the cultural background of the future engineer in view of the professional role she/he will play. In particular, those aspects of chemistry relevant in the field of industrial engineering will be privileged, among which for example: the study of chemical reactions and in particular of their spontaneity, the chemistry of metals, corrosion, electrochemistry, thermochemistry.
The student will acquire:
The aim of the course is to provide the student with the knowledge of chemistry that is essential to form the cultural background of the future engineer in view of the professional role she/he will play. In particular, those aspects of chemistry relevant in the field of industrial engineering will be privileged, among which for example: the study of chemical reactions and in particular of their spontaneity, the chemistry of metals, corrosion, electrochemistry, thermochemistry.
The student will acquire:
Knowledge and understanding of the relevant laws of physics (mechanics, electromagnetism, thermodynamics) and chemistry in the field of industrial engineering and understanding of the role of these laws in the formulation of representative models of tangible reality.
Knowledge and understanding of thermodynamics phenomena as well as models capable of representing them. Knowledge of systems and machines for the production and conversion of energy, with particular reference to turbomachinery and industrial combustion equipment. Understanding the role of different energy technologies in ensuring the environmental and economic sustainability of production.applied to energy systems and of fluid-dynamic
Students will be able to:
Applying knowledge and understanding related to the physical and chemical field to solve mono-disciplinary problems of chemistry, applied chemistry, mechanics, electromagnetism and theoretical thermodynamics as a basis for mechanical engineering problems.
Students will be able to:
Applying knowledge and understanding related to the physical and chemical field to solve mono-disciplinary problems of chemistry, applied chemistry, mechanics, electromagnetism and theoretical thermodynamics as a basis for mechanical engineering problems.
Prerequisites - Last names E-N
Prerequisites are not requested
Prerequisites - Last names O-Z
none
Teaching Methods - Last names E-N
About 70/80% of the time of the course will be spend in frontal lessons while the remaining practice exercises that will help the students in preparing their final exam
Teaching Methods - Last names O-Z
About 70/80% of the time of the course will be spend in frontal lessons while the remaining practice exercises that will help students in preparing their final exam
Type of Assessment - Last names A-D
The examination is performed with a written test which, if passed, can be followed, at the student choice, by an oral examination. The student must demonstrate knowledge of the entire program by answering open-ended questions and solving exercises.
Type of Assessment - Last names E-N
The examination is performed with a written test which, if passed, can be followed, at the student's choice, by an oral exam. The student must demonstrate knowledge of the entire program, answering open-ended questions and solving exercises.
Type of Assessment - Last names O-Z
The examination is performed with a written test which, if passed, can be followed, at the student's choice, by an oral exam. The student must demonstrate knowledge of the entire program, answering open-ended questions and solving exercises.
Course program - Last names E-N
Methods and Measurement; The Composition and Structure of the Atom; ; quantum theory and electronic structure of atoms; Elements, Atoms, Ions and the Periodic Table; Structure and Properties of Ionic and Covalent Compounds; Calculations and the Chemical Equation; States of Matter: Gases and Solids; Reactions and Solutions; Chemical and Physical Change: Energy, Rate and Equilibrium; Charge-Transfer Reactions: Acids and Bases and Oxidation-Reduction; chemical kinetics
Course program - Last names O-Z
Methods and Measurement; The Composition and Structure of the Atom; ; quantum theory and electronic structure of atoms; Elements, Atoms, Ions and the Periodic Table; Structure and Properties of Ionic and Covalent Compounds; Calculations and the Chemical Equation; States of Matter: Gases and Solids; Reactions and Solutions; Chemical and Physical Change: Energy, Rate and Equilibrium; Charge-Transfer Reactions: Acids and Bases and Oxidation-Reduction; chemical kinetics