1 / 18

Ab Initio Molecular Dynamics with a Continuum Solvation Model

CSC 2002 Conference, Vancouver, BC, 2 June 2002. Ab Initio Molecular Dynamics with a Continuum Solvation Model. Hans Martin Senn , Tom Ziegler University of Calgary. Outline. Background Car–Parrinello ab initio molecular dynamics The Projector-Augmented Wave (PAW) method

randy
Download Presentation

Ab Initio Molecular Dynamics with a Continuum Solvation Model

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. CSC 2002 Conference, Vancouver, BC, 2 June 2002 Ab Initio Molecular Dynamics with a Continuum Solvation Model Hans Martin Senn, Tom Ziegler University of Calgary

  2. Outline • Background • Car–Parrinello ab initio molecular dynamics • The Projector-Augmented Wave (PAW) method • Continuum solvation / The Conductor-like Screening Model (COSMO) • Continuum solvation within ab initio MD • Surface with smooth analytic derivatives • Surface charges as dynamic variables • Tests and first applications • Hydration energies • Conformers of glycine • CO insertion into Ir–CH3

  3. Nuclei Classical mechanics Electrons Density-functional theory Ab Initio Molecular Dynamics R. Car, M. Parrinello, Phys. Rev. Lett. 1985, 55, 2471 • Ab initio molecular dynamics Ab initio molecular dynamics Forces on nuclei derived frominstantaneous electronic structure • Car–Parrinello scheme for ab initio MD • Fictitious dynamics of the wavefunctions • Simultaneous treatment of atomic and electronic structure • Friction dynamics for minimizations

  4. The Projector-Augmented Wave (PAW) Method P.E. Blöchl, Phys. Rev. B 1994, 50, 17953 • Basis set: Augmented plane waves • Spatial decomposition of the wavefunction according to its shape • Smooth plane-wave expansion far from nuclei • Rapidly oscillating augmentation functions around the nuclei • Integrations for total energy and matrix elements decompose accordingly • Smooth parts in Fourier representation • One-centre parts on radial grids in spherical harmonics expansions • All-electron method • Frozen-core approximation

  5. Continuum Solvation Models • Implicit electrostatic solvation • “Solvent” = homogeneous, isotropic dielectric medium • Fully characterized by relative permittivity (r) • Electrostatic interactions • Solute polarizes the dielectric ( reaction field) Epol > 0 • Solute charge density interacts with polarized medium Eint < 0 • Solute electronic and atomic structure adapt (“back-polarization”) ∆Een > 0 • Repeat to self-consistency! • Electrostatic free energy • For a linear dielectric:

  6. The Solvation Energy • Non-electrostatic contributions • Cavity formation • Dispersion and exchange-repulsion • Approximately proportional to cavity surface area • Free energy of solvation • Neglect changes in thermal motion upon solvation

  7. The Conductor-Like Screening Model (COSMO) • Main approximations in COSMO 1. Dielectric with infinite permittivity (er ∞) • No volume polarization; polarization expressed as surface charge density only • Vanishing potential at the cavity boundary 2. Recover true dielectric behaviour by scaling • Derived for rigid multipoles in spherical cavity • f = f(er) = (er – 1) / (er + x) [x = 0, 1/2 for monopole, dipole] 3. Discretize cavity surface and surface charge • Surface segments carrying point charges qi • Energy expression is variational in qi

  8. Surface Charges as Dynamic Variables • Extended Lagrangean including solvation • Equations of motion for charges • Additional forces acting on the nuclei • Surface segments and charges implicitly depend on atomic positions via the surface construction • Forces obtained as analytic derivatives • Energy-conserving dynamics requires smooth derivatives • Segments/charges must not vanish or be created during the simulation • Each segment/charge must be unambiguously assigned to an atom • Conventional schemes for building the cavity are not compatible with this!

  9. Surface Construction • A surface construction compatible with AIMD • Surface = union of atomic spheres • Each sphere is triangulated • All segments and charges are retainedEach segment/charge moves rigidly along with its atom 4. A switching function effectively removes charges lying within another sphere from the energy expression • Qi = 1 if the charge is exposed on the molecular surface • Qi = 0 if the charge is buried • Smooth transition between “on” and “off”

  10. Switching Functions • Building the switching function • Rectangular pulse • Centred at d0 = Rsolv – c • Vanishes smoothly at d0 n = 1 n = 10 n = 24 h d • Atomic switching function d0 Rsolv • Total switching function • Charge is smoothly switched off if it lies within any one of the other spheres RAsolv RBsolv

  11. Rijc pot. |si – sj| Rounding the Edges… • Behaviour of hidden charges • Magnitude of switched-off charges physically undetermined • Problematic if charge becomes again exposed • Restoring potential • Added to the Lagrangean • Artificial self-interaction, acting only on hidden charges • Modified Coulomb potential at short range • Charges can collide at seams • Modified Coulomb potential • True 1/r behaviour replaced by linear continuationfor |si – sj| < Rijc • Rijc derived from average of self-interaction potentials

  12. Representation of the Solute Density • Decoupling of periodic images • Plane-wave-based methods always create periodic images • Artificial in molecular calculations • Electrostatic decoupling scheme in PAW • Model density • Superposition of atom-centred Gaussians • Coefficients determined by fit to true density • Reproduces long-range behaviour • Surface charges couple to model density • Not instrumental • Computationally convenient • 3–5 Gaussians per atom • Fitting procedure relays forces acting on the wave functions due to the charges

  13. 4.2 kJ/mol MUE: 3.2 kJ/mol 5.2 kJ/mol Parameterization and Validation • Parameterization • Free energies of hydration • Parameters: Solvation radii RIsolv, non-polar parameters b,g • Fit set: Neutral organic molecules containing C, H, O, N • Mean unsigned error (MUE) over whole set: 4.1 kJ/mol • On par with similar DFT/COSMO results

  14. A C Z B Conformers of Glycine • H-bonding patterns • Relative stabilities (kJ/mol) • Hydration energies (kJ/mol) • Zwitterion in solution • Most stable conformer • Not present in the gas phase

  15. Energy Conservation • Conservation of total energy • Glycine without and with continuum solvation • ∆t = 7 a.u., T ≈ 300 K (no thermostats, no friction) • Drift in total energy: solvation off +2.78  5Eh/ps per atom solvation on 1.43  5Eh/ps per atom • Energy is conserved

  16. RC A First Application • Carbonylation of methanol • “Monsanto” / ”Cativa” acetic-acid process • M = Rh, Ir • Via [MI3(CH3)(CO)2]– [MI3(COCH3)(CO)]– • AIMD simulation of CO insertion step • Solvent: iodomethane; T = 300 K • Slow-growth thermodynamic integration along d(CMe–CCO) • ∆A‡ = 111  (128) kJ/mol∆E‡ = 126  (155) kJ/mol; ∆S‡ = 60  (91) J/(K mol) • Dissociation of I– trans to incipient acyl! • Only in solution at finite temperature • Enthalpy of Ir–I bond traded for entropy of free (solvated) I–

  17. Summary • COSMO continuum solvation in AIMD • Surface charges as dynamic variables • Surface construction • Switching function smoothly disables unexposed charges • Smooth analytic derivatives wrt. atomic positions • Energy-conserving • Solvation energies • On par with other DFT/COSMO implementations • Modelling of finite-temperature and solvation effects

  18. Acknowledgments • Peter E. Blöchl,Institute of Theoretical Physics, Clausthal University of Technology, Germany • Peter M. Margl,Corporate R&D Computing, Modeling and Information Sciences, Dow • Rochus Schmid,Institute of Inorganic Chemistry, Munich University of Technology, Germany • Swiss National Science Foundation • NSERC • Petroleum Research Fund

More Related