General and Inorganic Chemistry
A.Y. 2020/2021
Learning objectives
According to the Medical Biotechnologies Bachelor's degree guidelines, the General and Inorganic Chemistry course provides the experimental and theoretical fundamentals of chemical sciences and introduces the students to their jargon and methodologies. Moreover, they will be trained about the basic principles of structure of the matter and of the molecular reactivity and thermodynamics, with a strong focus on the chemistry of aqueous systems.
Expected learning outcomes
A final goal of the course will be the acquisition of the necessary methodology and of the most correct language for the comprehension and elaboration of chemical concepts and data. Such a knowledge will pave the way for the study of the majority of the disciplines of the following semester and of the second year, in particular of Organic Chemistry and Biochemistry.
Lesson period: First semester
Assessment methods: Esame
Assessment result: voto verbalizzato in trentesimi
Single course
This course cannot be attended as a single course. Please check our list of single courses to find the ones available for enrolment.
Course syllabus and organization
Single session
Responsible
Lesson period
First semester
TEACHING METHODS
The educational activity of the course will be provided as frontal teaching and distance teaching (in synchronous modality). The presence in the classroom will be possible in shifts in compliance with anti-covid regulations.
The methods and criteria for participating in the lessons in attendance, which require a reservation with a special app, will be published on the Ariel pages of the teaching and/or by the teaching secretary of the course.
In case of a new suspension of frontal lessons, all students will be asked to switch to synchronous distance learning. Each hour of the lesson will be divided into 45" formal teaching followed by 15" discussion / interaction / question time.
All lectures will be recorded and available to students on dedicated platforms (e.g. Ariel, TEAMS, etc.).
Any notice regarding updates or also related to the evolution of the regulations imposed by Covid-19 will be published on the degree course Ariel website and on Ariel website of the individual courses as well as communicated by the teaching secretariat.
TEACHING RESOURCES
The program and reference material will not be changed. The latter will be made available on dedicated platforms (e.g. Ariel, TEAMS, etc.)
ASSESSMENT METHODS AND CRITERIA
Unless otherwise specified, the exams will be organized in the classroom and according to the reported learning methods. If the student will not be able to reach the exam center due to problems with COVID, other modalities may be considered (this applies only to exams scheduled until 31 December - 2020)
The educational activity of the course will be provided as frontal teaching and distance teaching (in synchronous modality). The presence in the classroom will be possible in shifts in compliance with anti-covid regulations.
The methods and criteria for participating in the lessons in attendance, which require a reservation with a special app, will be published on the Ariel pages of the teaching and/or by the teaching secretary of the course.
In case of a new suspension of frontal lessons, all students will be asked to switch to synchronous distance learning. Each hour of the lesson will be divided into 45" formal teaching followed by 15" discussion / interaction / question time.
All lectures will be recorded and available to students on dedicated platforms (e.g. Ariel, TEAMS, etc.).
Any notice regarding updates or also related to the evolution of the regulations imposed by Covid-19 will be published on the degree course Ariel website and on Ariel website of the individual courses as well as communicated by the teaching secretariat.
TEACHING RESOURCES
The program and reference material will not be changed. The latter will be made available on dedicated platforms (e.g. Ariel, TEAMS, etc.)
ASSESSMENT METHODS AND CRITERIA
Unless otherwise specified, the exams will be organized in the classroom and according to the reported learning methods. If the student will not be able to reach the exam center due to problems with COVID, other modalities may be considered (this applies only to exams scheduled until 31 December - 2020)
Course syllabus
Qualitative and quantitative aspects of chemistry (7 hours)
Course outline.
Elements of history of Chemistry: from alchemy to modern times. Mixtures and compounds. Dalton's atomic theory and the laws of chemical combination. Systematization of atomic properties: the periodic table of elements by Mendeleev.
Nucleosynthesis of light atoms and elements of the nucleosynthesis of heavy elements. Atoms, elements and isotopes: atomic number and atomic weight. The modern periodic table of elements.
Molecules, compounds and molecular formulas. Molecular weight and mass, molecular and formula weight. The Avogadro number and the concept of mole.
Compound names. Metals, nonmetals and metalloids. Oxides. Acids and bases. Salts. Ionic and molecular compounds.
Structure of matter (14 hours)
The atomic structure and the subatomic particles. the electromagnetic radiations and the atomic spectrum. The Bohr's atom: the quantum mechanical description of the atoms and the concept of wave function. Atoms configuration: quantum numbers and orbitals. Pauli's principle. Hund's rule. The electronic structure of atoms and its connection with the periodic table of elements. Periodicity of the atomic properties: atomic and ionic radius, ionization energies and electron affinity.
Chemical bonds and molecular structure: the electrons distribution in molecules. Ionic, covalent and metallic bonds. Lewis structures and the octet rule. Resonant structures. Electronegativity. The dipole moment in molecules and their polarity. The molecular shape according the VSEPR theory. The valence bond theory. Hybrid orbitals. Multiple bonds. Examples of inorganic and organic molecular structures. Molecular orbitals. Intermolecular weak forces. Hydrogen bonding.
Stoichiometry (9 hours)
Units and dimensional analysis.
Variance, standard deviation and standard error. Measurements, errors and significative figures.
Chemically relevant units. Moles, atomic weight and molecular weight. Elementary analysis and percentage composition. Equivalent weight and valence.
Chemical reactions: stoichiometry and balancing, yield and limiting agent. Aqueous phase reactions. Gas phase reactions. Net ionic equations. Concentration and dilution.
Oxidation number. Oxidation-reduction (redox) reactions and their balancing. Equivalent weight and normality.
States of matter (6 hours)
Gas properties. Ideal gases and their equation of state. Gas mixtures and partial pressure. Kinetic theory of gases. Effusion and diffusion. Real gases and their equation of state (Van der Waals).
Liquids properties. Gas diffusion in solutions. Transition state and phases equilibrium. Vapor pressure. Surface tension. Viscosity. Qualitative description of phase diagrams of water and carbon dioxide. The properties of water.
Solutions, dissolution and common solvents. Concentration units and solubility principles. Raoult's law. Colligative properties. Osmosis. Colloids and colloidal dispersions.
Solids properties. Ionic, covalent, molecular and metallic solids. Crystal lattices. Elements of X ray diffractometry.
The control of chemical reactions (12 hours)
The energetic landscape of chemical reactions: thermochemistry. Energy units. First law of thermodynamics. Internal Energy. General concepts of chemical thermodynamics. Enthalpy and reaction heat. Hess'law. Specific heat and thermal capacity. Calorimetry.
Second law of thermodynamics. Gibbs free energy and spontaneous processes. Chemical potential. Thermodynamic quantitative description of phase transitions.
Chemical equilibria: the mass action law, the equilibrium constant and the reaction quotient. Le Chatelier's principle.
Chemical kinetics. Reaction rates and mechanism of reaction. Activation energy and chemical catalysis.
Chemistry of aqueous solutions (6 hours)
Acids and bases chemistry. Water ionic product, pH, pOH and pKw. Strong and weak electrolytes. Arrhenius theory of acids and bases. Brönsted-Lowry theory of acids and bases. Conjugate acid-base couples. Aqueous solutions of weak and strong acids. Ionization degree. Polyprotic acids. Common ion effect. Lewis theory of acids and bases. Coordinate covalent (dative) bonds and complex ions. Acid-base reactions. Salt hydrolysis. Buffer solutions. Acid-base titrations and their stoichiometry. Acid-base indicators. pH calculations of solutions of acidic, basic and salts. Neutralization diagrams.
Low solubility salts. Product of solubility. Precipitation reactions. Common ion solubility. pH and solubility. Simultaneous equilibria. Redox titration.
Elements of bioinorganic chemistry (2 hours)
Natural aminoacids, pKa and isoelectric point. Transition metals and coordination chemistry in proteins: copper and zinc. Oxygen transport. Redox reactions of biological relevance.
Electrochemistry (8 hours)
Electrochemical and electrolytic cells. Standard reduction potentials. Electromotive force (emf) of a pile. Free energy and efm. Non-standard voltaic cells and Nernst equation. Emf and equilibrium constant. Concentration piles. Potentiometric determination of Kps and of pH. Indicator and reference electrodes. The pH meter. Electrolysis. Fuse salts, aqueous solutions and water electrolysis. Batteries and accumulators. Metal corrosion.
Course outline.
Elements of history of Chemistry: from alchemy to modern times. Mixtures and compounds. Dalton's atomic theory and the laws of chemical combination. Systematization of atomic properties: the periodic table of elements by Mendeleev.
Nucleosynthesis of light atoms and elements of the nucleosynthesis of heavy elements. Atoms, elements and isotopes: atomic number and atomic weight. The modern periodic table of elements.
Molecules, compounds and molecular formulas. Molecular weight and mass, molecular and formula weight. The Avogadro number and the concept of mole.
Compound names. Metals, nonmetals and metalloids. Oxides. Acids and bases. Salts. Ionic and molecular compounds.
Structure of matter (14 hours)
The atomic structure and the subatomic particles. the electromagnetic radiations and the atomic spectrum. The Bohr's atom: the quantum mechanical description of the atoms and the concept of wave function. Atoms configuration: quantum numbers and orbitals. Pauli's principle. Hund's rule. The electronic structure of atoms and its connection with the periodic table of elements. Periodicity of the atomic properties: atomic and ionic radius, ionization energies and electron affinity.
Chemical bonds and molecular structure: the electrons distribution in molecules. Ionic, covalent and metallic bonds. Lewis structures and the octet rule. Resonant structures. Electronegativity. The dipole moment in molecules and their polarity. The molecular shape according the VSEPR theory. The valence bond theory. Hybrid orbitals. Multiple bonds. Examples of inorganic and organic molecular structures. Molecular orbitals. Intermolecular weak forces. Hydrogen bonding.
Stoichiometry (9 hours)
Units and dimensional analysis.
Variance, standard deviation and standard error. Measurements, errors and significative figures.
Chemically relevant units. Moles, atomic weight and molecular weight. Elementary analysis and percentage composition. Equivalent weight and valence.
Chemical reactions: stoichiometry and balancing, yield and limiting agent. Aqueous phase reactions. Gas phase reactions. Net ionic equations. Concentration and dilution.
Oxidation number. Oxidation-reduction (redox) reactions and their balancing. Equivalent weight and normality.
States of matter (6 hours)
Gas properties. Ideal gases and their equation of state. Gas mixtures and partial pressure. Kinetic theory of gases. Effusion and diffusion. Real gases and their equation of state (Van der Waals).
Liquids properties. Gas diffusion in solutions. Transition state and phases equilibrium. Vapor pressure. Surface tension. Viscosity. Qualitative description of phase diagrams of water and carbon dioxide. The properties of water.
Solutions, dissolution and common solvents. Concentration units and solubility principles. Raoult's law. Colligative properties. Osmosis. Colloids and colloidal dispersions.
Solids properties. Ionic, covalent, molecular and metallic solids. Crystal lattices. Elements of X ray diffractometry.
The control of chemical reactions (12 hours)
The energetic landscape of chemical reactions: thermochemistry. Energy units. First law of thermodynamics. Internal Energy. General concepts of chemical thermodynamics. Enthalpy and reaction heat. Hess'law. Specific heat and thermal capacity. Calorimetry.
Second law of thermodynamics. Gibbs free energy and spontaneous processes. Chemical potential. Thermodynamic quantitative description of phase transitions.
Chemical equilibria: the mass action law, the equilibrium constant and the reaction quotient. Le Chatelier's principle.
Chemical kinetics. Reaction rates and mechanism of reaction. Activation energy and chemical catalysis.
Chemistry of aqueous solutions (6 hours)
Acids and bases chemistry. Water ionic product, pH, pOH and pKw. Strong and weak electrolytes. Arrhenius theory of acids and bases. Brönsted-Lowry theory of acids and bases. Conjugate acid-base couples. Aqueous solutions of weak and strong acids. Ionization degree. Polyprotic acids. Common ion effect. Lewis theory of acids and bases. Coordinate covalent (dative) bonds and complex ions. Acid-base reactions. Salt hydrolysis. Buffer solutions. Acid-base titrations and their stoichiometry. Acid-base indicators. pH calculations of solutions of acidic, basic and salts. Neutralization diagrams.
Low solubility salts. Product of solubility. Precipitation reactions. Common ion solubility. pH and solubility. Simultaneous equilibria. Redox titration.
Elements of bioinorganic chemistry (2 hours)
Natural aminoacids, pKa and isoelectric point. Transition metals and coordination chemistry in proteins: copper and zinc. Oxygen transport. Redox reactions of biological relevance.
Electrochemistry (8 hours)
Electrochemical and electrolytic cells. Standard reduction potentials. Electromotive force (emf) of a pile. Free energy and efm. Non-standard voltaic cells and Nernst equation. Emf and equilibrium constant. Concentration piles. Potentiometric determination of Kps and of pH. Indicator and reference electrodes. The pH meter. Electrolysis. Fuse salts, aqueous solutions and water electrolysis. Batteries and accumulators. Metal corrosion.
Prerequisites for admission
No knowledge are required
Teaching methods
The course is based on lectures. Class attendance is mandatory
Teaching Resources
Theory
N. J. Tro, Chimica un Approccio Molecolare; Ed. EdiSES
Stoichiometry
P. Michelin Lausarot, G. A. Vaglio Stechiometria per la Chimica Generale. Ed. Piccin
N. J. Tro, Chimica un Approccio Molecolare; Ed. EdiSES
Stoichiometry
P. Michelin Lausarot, G. A. Vaglio Stechiometria per la Chimica Generale. Ed. Piccin
Assessment methods and Criteria
The examination will be performed in a written form and divided into two parts: the first one will be a multiple choice test, the second one an open answer test. The positive result of the former will be mandatory for the access to the latter. The final mark will be computed as a sum of the two marks.
CHIM/03 - GENERAL AND INORGANIC CHEMISTRY - University credits: 8
Lessons: 64 hours
Professors:
Mollica Luca, Villa Alberto
Professor(s)