Quantum Geochemistry

Principles 1) Some recalls on Physical basis:1-1) roman";"="">  Statistical interpretation of a wave function1-2) Effect of an external potential on the time-dependent and time-independent Schrödinger equation1-3) The Quantum Mechanical Hamiltonian1-4) The postulates of Quantum Mechanics (Operators and eigenvalue equations; Eigenvalue equations in vector space; The expectation value postulate; The uncertainty principle; Eigenfunction sets)1-5)Probability density and Probability Current/p>1-6)The Schrödinger equation in momentum space and generalized coordinates1-7)  The Harmonic oscillator – general representationpx; margin-top: 0cm; margin-bottom: 0cm; margin-left: 70.9pt; text-indent: -52.9pt;">1-8)Thermal energy and nuclear motion Methods2) Gaussian Basis Sets (Exponents optimization; Polarized and diffuse functions)3)  Plane waves (LDA; GGA; PWSCF; LAPW )4)Pseudo-potentials5) size: 14px;">Functionals5-1) Harthree-Fock (HF and electron correlation; Restricted HF, Restricted Open HF)5-2) Density Functionals (The Colle-Salvetti Theorem and the Lee-Yan-Parr approximation)10pt; text-indent: -52.9pt;">5-3) Hybrid functional (Local Density Approximation; General Gradient Approximation) Generalities about Observables6) Thermodynamic parameters (to be expanded) alibri , sans-ser^ 7) Thermophysical parameters (to be expanded) 8) Spectroscopic parameters (to be expanded) Applications 9) Gaseous species: The isolated gaseous molecule: electron energy and zero-point energy; Electron-convention and Ion-Convention; Adiabatic vs Vertical IMolar Entropy and Molar Gibbs free energy of formation from the elements; Molar Volume; Dissociation energy of some geologically relevant gaseous species10)  &nbSolvation energy; Scaling from “absolute” to “conventional” magnitudes; Thermochemical cycles and the “Hydronium Ion” [H3O]+; Entropy of aqueous species; Basicity of acids: The Acetic Acid as an example; The pKa scale of organic and inorganic acids; The individual ionic activity coefficient in acqueous solutions of different ionic strenght; Thermodynamic properties of aqueous species with heavy atoms;11) Silicate Melts: Silicate melts as dielectric media; Tetrahedral symmetry: the role of sp3 hybridization; The effect of ad-ions on the orbital energy on oxygen centers: inner and external orbitals; Polymeric structures and the role of electron localization – electron delocalization in determining bond strength and medium range symmetry; Silicate melts as solvents: applications of The Scaled Particle Theoryt" style="font-size:12)  Crystals12-1) Lattice geometry (Translational symmetry; Unit Cell; Point Groups; Space Groups; Symmetry restrictions imposed by periodicity; Basis sets effect; HF for open shell crystals UHF for periodic systems)ly: Calibri , sans-serif;">12-2) Periodic boundary conditions and Bloch functions (Density of states; Bond structure; Fermi Energy and Fermi Surface)12-3) Density of States, Bond Structure Fermi Energy and Fermi Surface12-4) Lattice Dynamics and Thermal Properties (Model Potential Functions; Harmonic Approximation; Born Matrix and Dispersion Relation; Experimental Methods and empirical fittings; Quantum Mechanical derivation of Force Constants)an>12-5) Thermal stress and electron delocalization (Bader Analysis; Topological weaknesses; Thermally-induced bond-weakening; Buckenau assumption and RUM modes)  12-6) Observables (Total Energy and related Properties; The formation energy and other energy differences; The equilibrium geometry; EOS and Phase transitions; Bulk modulus and elastic constants; Thermodynamic properties: energy quantization and phonons; Thermodynamic functions and Density of States; Quasi harmonic Model; Thermal expansion;; The asymmetric potential well: evidences from discrete static potential calculations; The Coulomb, repulsive and dispersive potentials;; Madelung Energy; Thermal energy and thermal expansion: the shift of the potential energy minimum; Surface Energy; Surfaces and Local Defect; One electron density matrix and related observables ) 13) Isotopomeric energy and isotopic fractionation 13-1) Nuclear mass and vibrational properties (Separative effect and equilibrium exchanges; Bigeleisen-Mayer approximation; Kieffer rules; The “Isotopic Hergodicity Principle”; Reaction Kinetics and isotope exchange; Diffusion induced Isotope fractionation. 13-2) Nuclear Mass and Relativistic effects001pt;tab-stops:0cm"> Calibri, sans-serif;">13-3) Ab-initio Stable Isotopes (C-H-O-S)13-4) Ab-initio transition metals (Fe-Cu-Cr)13-5) Ab-initio Metallomics (Ca) ; margin-top: 0cm; margin-bottom: 0cm; margin-left: 21.3pt;">APPENDIX1) Operators and eigenvalue equations (Self-adjoint form and Hermite equations; Properties of eigenfunctions; Eigenfunction expansions; Orthogonality of eigenfunctions; Adjoint operators and Hermitian symmetry)2) Separation of differential equations3) The metric tensor 4) Reciprocal Lattice 5) The Block Theorem6); line-height: normal;" times="" new="" ro Plane waves7) Gaussian Functions ize: 14px;">