User:Physchim62/PCSI Chemistry
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Contents
The architecture of matter
Periodicity
- Introduction to the quantum numbers: n, l, ml, ms. Existence of quantised energy levels in the atom, degeneracy of these levels.
- Electronic configuration of an atom or an ion (in the ground state): Pauli’s exclusion principle, Aufbau rules.
- Construction of the periodic table: structure in blocks.
- Trends in certain atomic properties: ionisation energy, electron affinity and Mulliken electronegativity.
- Core electrons, valence electrons.
The quantum model of the atom
- Probability density for the electron in a hydrogen-like atom.
- Polyelectronic atoms: orbital approximation, Slater's effective nuclear charge; energies of hydrogen-like and polyelectronic atoms.
- Atomic radius.
- Ionic radius.
Electronic structure of molecules
- Localised covalent bond: Lewis notation.
- Octet rule.
- Delocalised covalent bond: mesomerism and resonance.
- Prediction of the geometry by the VSEPR method.
- Description of homonuclear diatomic molecules: construction of molecular orbitals by LCAO, orbital overlap; discussion of the MO diagrams of the homonuclear diatomic of the second period.
Low energy interactions
- Van der Waals forces.
- Hydrogen bonds.
Chemical kinetics
Rates in chemical kinetics
- Rates of disappearance of a reactant and of formation of a product, in the case of a closed reactor of uniform composition.
- Progress of a reaction represented by a single stoichiometric equation.
Kinetic factors. Rate laws
- Rate law: reaction with integral order; reactions with non-integral order. Examples.
- Degeneracy of the order.
- Half-life with respect to a limiting reactant, in the case of zeroth, first and second order reactions.
- Arrhenius' law (empirical); activation energy.
Reaction mechanisms in homogeneous kinetics
- Formal kinetics: strictly reversible reactions, parallel reactions, consecutive reactions.
- Steady-state approximation.
- Elementary processes, molecular of a process, reaction intermediates, transition state.
- Qualitative microscopic interpretation of the role of temperature and concentration on the reaction rate.
- Mechanisms by stages. Rate determining step.
- Mechanisms in chain. Chain length.
Structure, reactivity and synthesis in organic chemistry
Stereochemistry of organic molecules
- Newman representations, Cram representations, perspective.
- Configurational stereoisomerism: Z & E, R & S, enantiomers and diastereomers.
- Conformation: ethane, butane, cyclopean, and mono- and disubstituted cyclohexanes.
Reactivity of the carbon-carbon double bond
- Electrophilic addition and radical addition (hydration, hydrohalogenation, halogenation); mechanisms.
- Cleavage by ozonolysis (without mechanism).
Grignard reagents
- Preparation of Grignard reagents, experimental conditions.
- Nucleophilicity and basicity of Grignard reagents.
- Reactions with carbonyl groups (ketones, aldehydes, esters, acyl chlorides, acid anhydrides), with carbon dioxide, with nitriles and with epoxides.
Carbon-halogen bonds
- Nucleophilic substitution reactions: SN1 and SN2 limiting mechanisms; stereochemistry.
- Elimination reactions: E2 limiting mechanism, stereochemistry.
Carbon-nitrogen single bonds
- Basicity of amines.
- Nucleophilic reactivity: alkylation (mechanism).
Carbon-oxygen single bonds
- Acid-base properties of alcohols
- Preparation of ethers: Williamson reaction (mechanism)
- Transformation of an alcohol to an monohalogenated derivative: with HX (mechanism); with PX3 and SOCl2 (without mechanism).
- Intramolecular dehydration of an alcohol under acidic conditions: formation of an alkene.
Chemical thermodynamics
Applications of the first law of thermodynamics
Models used for the study of transformations
- Isobaric and isochoric reactors, isothermal and adiabatic reactors.
- Heat transfer during isochoric and isobaric transformations.
Standard molar quantities
- Standard states of a pure component: ideal gas and condensed phase; standard molar quantity.
- Transformation in a closed system: standard internal energy, standard enthalpy, variation with temperature.
- Sign of the enthalpy change for and endothermic/exothermic reaction.
- Thermal effects in an isobaric reactor:
Measurement of standard thermodynamic quantities
- Standard enthalpy change of formation of a pure substance.
- Discontinuity in ΔrH when one of the species changes state.
Equilibria in aqueous solution
- Concept of an acid/base pair, predominance as a function of pH.
- Simple pH calculations (common solutions, buffer solutions).
- Complexes: definition, stability constant (or dissociation constant). Predominance.
- Sparingly soluble compounds, precipitation criteria, solubility.
- Redox pairs: electrode potential; Nernst equation.
- Redox reactions, equilibrium constant, prediction of the direction of a reaction.
- Titrations: acid-base, redox, compleximetric, precipitation.