Molecular Hamiltonian operator and its Born-Oppenheimer approximation; electronic Schroedinger Equation; hydrogen atomic orbitals; electronic spin and its representation; Slater's determinants; relativistic effects; Hartree-Fock (HF) and Hartree-Fock-Roothaan methods; restricted (RHF) and unrestricted (UHF) wavefunctions; energy derivatives for the Hartree-Fock methodl spin eigenfunctions and multi-determinat wavefunctions; molecular orbital instability (RHF versus UHF); atomic basis sets; basis set superposition error; potential energy surfaces and their stationary points; rotational and vibrational molecular motion energy levels; atomization, formation and bond energy and enthalpy; intermolecular forces: electrostatic, inductive and dispersion interactions; distortion and conjugation energy; ionization potentials and Koopman's approximation; electronic affinity and excited states; electrostatic molecular potential and its multipolar decomposition; molecule/static fields interaction; electron density partition approaches; fundamentals of reaction theory (frontier molecular orbitals and "hard-soft acid-base"). Computer-based exercises with electronic structure codes and visualization programs.