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Politecnico di Torino
Academic Year 2017/18
16AHMLZ, 15AHMNX, 15AHMOA, 15AHMOD, 16AHMLN, 16AHMLP, 16AHMLS, 16AHMLX, 16AHMMA, 16AHMMB, 16AHMMC, 16AHMMH, 16AHMMK, 16AHMMN, 16AHMMO, 16AHMMQ, 16AHMPC, 16AHMPI, 16AHMPL
Chemistry
1st degree and Bachelor-level of the Bologna process in Aerospace Engineering - Torino
1st degree and Bachelor-level of the Bologna process in Electronic Engineering - Torino
1st degree and Bachelor-level of the Bologna process in Computer Engineering - Torino
Espandi...
Teacher Status SSD Les Ex Lab Tut Years teaching
Angelini Emma Paola Maria Virginia ORARIO RICEVIMENTO     58.5 18 3 27 21
Armandi Marco   A2 CHEM-06/A 58.5 18 3 27 11
Bodoardo Silvia ORARIO RICEVIMENTO O2 ICHI-01/A 58.5 18 3 27 17
Fina Alberto ORARIO RICEVIMENTO O2 CHEM-06/A 58.5 18 3 27 14
Fiorilli Sonia Lucia ORARIO RICEVIMENTO O2 CHEM-06/A 58.5 18 3 27 16
Fiorilli Sonia Lucia ORARIO RICEVIMENTO O2 CHEM-06/A 58.5 18 3 27 16
Francia Carlotta ORARIO RICEVIMENTO A2 CHEM-06/A 58.5 18 3 27 15
Geobaldo Francesco ORARIO RICEVIMENTO PO CHEM-06/A 58.5 18 3 27 24
Gerbaldi Claudio ORARIO RICEVIMENTO O2 CHEM-06/A 58.5 18 3 27 14
Gerbaldi Claudio ORARIO RICEVIMENTO O2 CHEM-06/A 58.5 18 3 27 14
Grassini Sabrina ORARIO RICEVIMENTO O2 ICHI-01/A 58.5 18 3 27 17
Grassini Sabrina ORARIO RICEVIMENTO O2 ICHI-01/A 58.5 18 3 27 17
Onida Barbara ORARIO RICEVIMENTO AC CHEM-06/A 58.5 18 3 27 22
Penazzi Nerino ORARIO RICEVIMENTO     58.5 18 3 27 15
Ronchetti Silvia Maria ORARIO RICEVIMENTO RC CHEM-06/A 58.5 18 3 27 22
Saracco Guido ORARIO RICEVIMENTO PO CHEM-06/A 58.5 18 3 27 2
Savorani Francesco   A2 CHEM-06/A 58.5 18 3 27 10
Savorani Francesco   A2 CHEM-06/A 58.5 18 3 27 10
SSD CFU Activities Area context
CHIM/07 8 A - Di base Fisica e chimica
Subject fundamentals
The course aims to provide the basic knowledge necessary for the interpretation of chemical phenomena, for the understanding of the structure and properties of crystalline solids and for the understanding and calculation of energy phenomena related to chemical and electrochemical systems.
Expected learning outcomes
The course aims at providing the necessary background for the interpretation of chemical phenomena, for the understanding of the structure and properties of molecules and crystalline solids, and the comprehension and handling of energetic phenomena concerning chemical and electrochemical systems.
Prerequisites / Assumed knowledge
To make profit of the course it is required to master the basic notions of general chemistry, the symbols of elements and compounds, the simplest nomenclature both organic and inorganic, the balancing of elementary stoichiometric reactions.
Contents
ATOM
Constitution of the nucleus, structure of the hydrogen atom and atomic models (Bohr and quantum-mechanical)
Quantum numbers, exclusion principle and Hundt rule
Spatial form of s,p and d orbitals

CLASSIFICATION OF THE ELEMENTS AND PERIODIC TABLE
Electronic configuration of the elements and periodicity in the chemical and physical properties
Atomic radius, ionization energy and electron affinity
Subdivision into metals, non-metals and semimetals.
Basics on the main groups of the periodic table and some transition metals.

THE CHEMICAL BOND
Bond: ionic, covalent, metallic. Intermolecular interactions.
Covalent bond: single, double and triple.
Molecular geometry, hybridisation and resonance.
Notes on the theory of molecular orbitals.

NOMENCLATURE, FORMULAS AND STOICHIOMETRY
Atomic and molecular mass, the mole, Avogadro's constant.
Acid-base reactions and formation of salts.
Oxidation state and balancing of redox reactions.
Mass relationships in a chemical reaction, limiting reagent.
Combustion reactions

GASEOUS STATE
Ideal gas laws. State equation of ideal gases.
Equilibrium distribution of kinetic energies in an ideal gas (Boltzmann).
Liquefaction of a gas.

LIQUID STATE
Vapour pressure of pure liquids.
Solutions: ways to express concentration. Dissociation and ionization degree. Colligate properties of solutions, both electrolytic and non. Definition of acid and base according to Arrhenius, Brønsted and Lewis. Ostwald dilution law.
Ionic product of water, pH and pOH.

SOLID STATE
Unit cell and structure of simplestcrystalline solids. Crystal lattices. Classification of solids.

CHEMICAL KINETICS AND CATALYSIS
Reaction rate and order. Arrhenius equation. Activation energy. Catalysis and catalysts.

CHEMICAL EQUILIBRIUM
Mass action law. Equilibrium constant. Homogeneous and heterogeneous chemical equilibria. Le Chatelier principle and influence of the temperature on the equilibrium.


CHEMICAL THERMODYNAMICS
First, second and third Principle. Reaction enthalpy and Hess law. Change in entropy and free energy of a reaction. Spontaneity criterion.

ELECTROCHEMISTRY
Normal and effective potential of an electrode. Electrochemical cells and Nernst equation. Electrochemical force of a cell. Reactivity of metals with ocids, oxidizing or not. Electrolysis and Faraday laws.

ORGANIC CHEMISTRY
Nomenclature and properties of the main organic compounds. Most common functional groups and their main reactions. Isomerism: structural, geometric, conformational.
Delivery modes
PRACTICAL
During practicals no new subject is dealt with, but only the numerical and computational of some subjects, among which:
' Survey of inorganic nomenclature
' Mole, gram-atom, molecular weight.
' Mass relationships in chemical reactions
' Redox reactions and their balancing.
' Ideal gases laws.
' Colligate properties of solutions.
' Chemical equilibria (homogeneous and heterogeneous)
' Reaction enthalpy (Hess law)
' pH and equilibria in aqueous solutions
' Nernst equation concerning an electrode or a cell.
' Faraday Laws

LABORATORY ACTIVITY
' Ideal gas laws
' Precipitation reactions
' Acid o-base titration
' Redox reactions
' pH measurement
' Daniell cell
Texts, readings, handouts and other learning resources
PRINCIPLES OF GENERAL CHEMISTRY (International Edition). Author: Martin Silberberg. Publisher: MgGraw-Hill
Assessment and grading criteria
The exam aims to assess the knowledge of inorganic and organic general chemistry acquired by the student during the course. The written exam also aims to verify the student's ability to solve stoichiometric calculations on chemical and electrochemical reactions, thermochemical equations, gas and liquid solutions.The examination consists of a computer test followed by a written test and, if required, by an oral test. No teaching material is allowed in any test.The duration of the computer test is 30 minutes and the test consists of 15 multiple choice questions. The maximum score achievable at the computer test is 12. If the score achieved at the test is less than 8, the examination is registered as failed. If the score is in the range 8-12 the student must attend the written test, consisting of both exercises and theoretical questions. The duration of the written test is 1 hour. The written test allows achieving a maximum score of 18. If the score obtained in the written test is less than 10, the examination is registered as failed. The final mark is the sum of the marks obtained at the computer test and the written test.
If the final grade is equal to or greater than 18/30, the student has the opportunity to request and sit for an additional oral examination. In this case, the final vote will also take into account the oral test. In the absence of the oral examination requested by the student, the final grade will be the one obtained from the test and written examination.
In addition, the teacher can always convene the student for an oral examination, in order to confirm the writ

Programma definitivo per l'A.A.2017/18
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