CHIMICA GENERALE ED INORGANICA
(objectives)
Training objectives The course aims to provide students with an introduction to the language and methodology of study of chemical phenomena of a general nature. The course, both through frontal lessons and through exercises, intends to provide the student with knowledge to make her/him able to write the structure formulas of the main inorganic compounds and their nomenclature, to use the mole and the molar relationships in chemical reactions, to know the fundamental concepts of chemical thermodynamics for the study of the aggregation states of the matter, the solutions and the chemical balances with particular attention to the acid-base equilibria and precipitation, to know also the fundamental concepts of chemical kinetics. The knowledge of these concepts is fundamental to undertake the study of the successive courses that characterize the degree course.
Expected results At the end of the course the student must show: 1) Knowledge and understanding: to know the fundamental principles of general chemistry to describe the matter and its properties: the atomic structure, the properties of the elements and their ability to form compounds, the molecular structures, the chemical reactions, energy exchanges, the states of matter, chemical kinetics, equilibrium in solution, acid-base properties; 2) ability to apply knowledge and understanding: having acquired application skills with reference to the balancing of reactions, stoichiometric calculations and problem solving on colligative properties, chemical equilibria, acid-bases reactions and on the solubility product; 3) Autonomy of judgement: to be able to independently evaluate and solve problems concerning the contents of the course; 4) Communicative skills: having developed a good oral and written communication capacity of the acquired concepts; 5) Learning skills: to be able to deepen the topics in different contexts and independently.
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Code
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17547 |
Language
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ITA |
Type of certificate
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Profit certificate
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Credits
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7
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Scientific Disciplinary Sector Code
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CHIM/03
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Contact Hours
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40
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Laboratory Hours
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16
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Type of Activity
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Basic compulsory activities
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Group: 1
Derived from
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118923 GENERAL AND INORGANIC CHEMISTRY in Natural and Environmental Sciences L-32 Sanna Nico
(syllabus)
1. Introduction States of aggregation of matter. Homogeneous and heterogeneous systems. Chemical elements and substances. Main techniques of separation. Chemical and physical transformations. Energy and chemical transformations. Intensive and extensive properties of matter. Fundamental laws of physics. The atom: protons, neutrons and electrons. Atomic number and mass number: isotopes. Atomic masses and relative atomic masses. Chemical symbols and their quantitative meaning. Molecular compounds and ionic compounds. Relative molecular mass. Avogadro number. The mole concept.
2. Chemical formulas and equations Chemical equations and balance. Kind of reactions: combinations, decomposition and combustion. Chemical analysis by combustion. Balanced equations and quantitative information. The concept of limitant reagent. Chemical reaction in solution: acid-base and precipitation. Balancing redox equations. Concentration of solutions and corresponding units.
3. Atomic structure Electromagnetic radiation. Bohr model of the hydrogen atom. Atomic spectra. De Broglie and the wave nature of matter. Heisenberg's uncertainty principle. Schrodinger equation. Wave-particle duality. Atomic orbitals. Quantum numbers. Pauli exclusion principle. Electronic configuration of the elements. Principle of Aufbau. The periodic system of the elements. Periodic properties: Dimensions of atoms and ions, ionization energy, electron affinity. Metals, non-metals and metalloids. Notes on coordination compounds and their biological significance.
4. The chemical bond Ionic and covalent bonding. Bond properties: order, distance and energy. Electronegativity and Dipolar moment. Lewis's structures. VSEPR model and geometry of molecules. Chemical bond theory: hybrid orbitals and resonance theory in chemistry. Magnetic properties of matter. Intermolecular forces. Hydrogen bond.
5. The gaseous state Ideal gas state equation. Dalton's Law for gaseous mixtures. Density and relative density of gases and gaseous mixtures. Average molecular mass of a gaseous mixture. Kinetic-molecular theory and velocity distribution. Graham's effusion law. Experimental methods for the determination of the molecular masses of gaseous substances. Real gases, Van der Waals equation.
6. Condensed states The Liquid state Intramolecular and intermolecular interactions. Intermolecular interactions of an electrostatic nature. Enthalpy of vaporization and its dependencies. Hydrogen bond. Phase's equilibria. Vapour pressure. Phase transitions and related enthalpies. Clausius-Clapeyron equation. One component phase diagram. Water Phase diagram of water. The Solid state Crystalline lattices and elementary cells. Molecular, ionic, covalent and metallic solids. Polymorphism and allotropy. X-ray diffraction. Definition of solids based on symmetry and intermolecular interactions.
7. Chemical thermodynamics Definition of thermodynamic system. Status functions. Cyclic and open transformations. Reversible and irreversible transformations. Heat, work and internal energy. First principle of thermodynamics. Enthalpy and Hess's law. Entropy. Second principle of thermodynamics. Spontaneous processes. Free energy. Third principle of thermodynamics. Introduction to the concept of chemical equilibrium.
8. Solutions Solubility and dissolving processes. Gas solutions in liquids. Enthalpy of dissolution and effect of temperature on solubilization processes. Ideal solutions and real solutions. Raoult's law. Ebullioscopic elevation and cryoscopic lowering. Colligative properties of the ideal solutions and determination of the molecular masses of compounds. Osmosis. Not ideal solutions. Fractional distillation. Azeotropic mixtures. Henry's law. Activity and ionic strength.
9. Chemical equilibrium Spontaneous processes and thermodynamic equilibrium in chemical reactions. Mass action law. Isoterm and isochoric of van't Hoff. Homogeneous equilibria. The principle of Le Chatelier. Effect of the variation in concentration of a reagent or a product on equilibrium. Effect of variation of volume, pressure and temperature on homogeneous equilibria. Heterogeneous equilibria.
10. Equilibria in Solution Acid-base equilibria: General definitions (Arrhenius, Broensted-Lowry, Lewis). Strength of acids and bases and equilibrium constants. Molecular structure and properties of acid-base. Water autoionization. The pH and the pOH. PH calculation of acidic, basic and saline solutions. Buffer solutions. Solubility and solubility product of salts.
11. Chemical Kinetics Reaction rate. Kinetic laws and integrated kinetic laws. Order and molecularity of a reaction. Arrhenius equation. Activation energy. Kinetic mechanism of reactions. Collision theory and theory of activated complex. Catalysis.
12. Electrochemical Galvanic cells. Electrode and electrode reaction. Standard potential. Thermodynamics of galvanic cells. Nerst equation.
Stoichiometry: Mole. Molecular and minimal formulas. Nomenclature of the main inorganic compounds. Chemical equations and ponderal ratios. Limiting reactive. Law of gases and gaseous species in chemical reactions. Indirect analysis. Solutions and volumetric analysis. Gaseous, homogeneous and heterogeneous chemical balances. Thermochemistry and thermodynamics of reactions. Colligative properties of non-electrolytes and electrolytes solutions. PH calculation of acid, base and salts solutions. Buffer solutions. Solubility and solubility product of salts.
(reference books)
Recommended texts;
M. Speranza et al., General and inorganic chemistry, Edi-Ermes Editor (2013).
F. Cacace and M. Schiavello, Stoichiometry, Bulzoni Editor (1995).
NOTE: The teacher will communicate at the beginning of the course the link to the additional teaching material available to the students.
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Dates of beginning and end of teaching activities
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From to |
Delivery mode
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Traditional
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Attendance
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not mandatory
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Evaluation methods
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Written test
Oral exam
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Group: 2
Teacher
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GARZOLI Stefania
(syllabus)
1. Introduction States of aggregation of matter. Homogeneous and heterogeneous systems. Chemical elements and substances. Main techniques of separation. Chemical and physical transformations. Energy and chemical transformations. Intensive and extensive properties of matter. Fundamental laws of physics. The atom: protons, neutrons and electrons. Atomic number and mass number: isotopes. Atomic masses and relative atomic masses. Chemical symbols and their quantitative meaning. Molecular compounds and ionic compounds. Relative molecular mass. Avogadro number. The mole concept.
2. Chemical formulas and equations Chemical equations and balance. Kind of reactions: combinations, decomposition and combustion. Chemical analysis by combustion. Balanced equations and quantitative information. The concept of limitant reagent. Chemical reaction in solution: acid-base and precipitation. Balancing redox equations. Concentration of solutions and corresponding units.
3. Atomic structure Electromagnetic radiation. Bohr model of the hydrogen atom. Atomic spectra. De Broglie and the wave nature of matter. Heisenberg's uncertainty principle. Schrodinger equation. Wave-particle duality. Atomic orbitals. Quantum numbers. Pauli exclusion principle. Electronic configuration of the elements. Principle of Aufbau. The periodic system of the elements. Periodic properties: Dimensions of atoms and ions, ionization energy, electron affinity. Metals, non-metals and metalloids. Notes on coordination compounds and their biological significance.
4. The chemical bond Ionic and covalent bonding. Bond properties: order, distance and energy. Electronegativity and Dipolar moment. Lewis's structures. VSEPR model and geometry of molecules. Chemical bond theory: hybrid orbitals and resonance theory in chemistry. Magnetic properties of matter. Intermolecular forces. Hydrogen bond.
5. The gaseous state Ideal gas state equation. Dalton's Law for gaseous mixtures. Density and relative density of gases and gaseous mixtures. Average molecular mass of a gaseous mixture. Kinetic-molecular theory and velocity distribution. Graham's effusion law. Experimental methods for the determination of the molecular masses of gaseous substances. Real gases, Van der Waals equation.
6. Condensed states The Liquid state Intramolecular and intermolecular interactions. Intermolecular interactions of an electrostatic nature. Enthalpy of vaporization and its dependencies. Hydrogen bond. Phase's equilibria. Vapour pressure. Phase transitions and related enthalpies. Clausius-Clapeyron equation. One component phase diagram. Water Phase diagram of water. The Solid state Crystalline lattices and elementary cells. Molecular, ionic, covalent and metallic solids. Polymorphism and allotropy. X-ray diffraction. Definition of solids based on symmetry and intermolecular interactions.
7. Chemical thermodynamics Definition of thermodynamic system. Status functions. Cyclic and open transformations. Reversible and irreversible transformations. Heat, work and internal energy. First principle of thermodynamics. Enthalpy and Hess's law. Entropy. Second principle of thermodynamics. Spontaneous processes. Free energy. Third principle of thermodynamics. Introduction to the concept of chemical equilibrium.
8. Solutions Solubility and dissolving processes. Gas solutions in liquids. Enthalpy of dissolution and effect of temperature on solubilization processes. Ideal solutions and real solutions. Raoult's law. Ebullioscopic elevation and cryoscopic lowering. Colligative properties of the ideal solutions and determination of the molecular masses of compounds. Osmosis. Not ideal solutions. Fractional distillation. Azeotropic mixtures. Henry's law. Activity and ionic strength.
9. Chemical equilibrium Spontaneous processes and thermodynamic equilibrium in chemical reactions. Mass action law. Isoterm and isochoric of van't Hoff. Homogeneous equilibria. The principle of Le Chatelier. Effect of the variation in concentration of a reagent or a product on equilibrium. Effect of variation of volume, pressure and temperature on homogeneous equilibria. Heterogeneous equilibria.
10. Equilibria in Solution Acid-base equilibria: General definitions (Arrhenius, Broensted-Lowry, Lewis). Strength of acids and bases and equilibrium constants. Molecular structure and properties of acid-base. Water autoionization. The pH and the pOH. PH calculation of acidic, basic and saline solutions. Buffer solutions. Solubility and solubility product of salts.
11. Chemical Kinetics Reaction rate. Kinetic laws and integrated kinetic laws. Order and molecularity of a reaction. Arrhenius equation. Activation energy. Kinetic mechanism of reactions. Collision theory and theory of activated complex. Catalysis.
12. Electrochemical Galvanic cells. Electrode and electrode reaction. Standard potential. Thermodynamics of galvanic cells. Nerst equation.
Stoichiometry: Mole. Molecular and minimal formulas. Nomenclature of the main inorganic compounds. Chemical equations and ponderal ratios. Limiting reactive. Law of gases and gaseous species in chemical reactions. Indirect analysis. Solutions and volumetric analysis. Gaseous, homogeneous and heterogeneous chemical balances. Thermochemistry and thermodynamics of reactions. Colligative properties of non-electrolytes and electrolytes solutions. PH calculation of acid, base and salts solutions. Buffer solutions. Solubility and solubility product of salts
(reference books)
Testi consigliati:
Brian B. Laird, "Chimica Generale" Ed. McGraw-Hill.
J.TRO, "Chimica" Ed. Edises
NOTA: Il docente comunicherà all’inizio del corso il link all’ulteriore materiale didattico a disposizione degli studenti.
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Dates of beginning and end of teaching activities
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From to |
Delivery mode
|
Traditional
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Attendance
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not mandatory
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Evaluation methods
|
Written test
Oral exam
|
|
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