Ab initio calculation on He3+ of interest for semiempirical modelling of Hen+ Ivana Paidarová a), Rudolf Polák a), František Karlický b), Daniel Hrivňák.

Slides:

Advertisements

Similar presentations

Basis Sets for Molecular Orbital Calculations

Advertisements

Philosophical Transactions A

The Materials Computation Center, University of Illinois Duane Johnson and Richard Martin (PIs), NSF DMR OBJECTIVE: Accelerate.

Quantum Mechanics Calculations II Apr 2010 Postgrad course on Comp Chem Noel M. O’Boyle.

68th OSU International Symposium on Molecular Spectroscopy TH08

Abstract Potentials Rare Gas Crystals References Solid and gas phase properties of argon as a test of ab initio three-body potential. František Karlický.

Dynamics of Vibrational Excitation in the C 60 - Single Molecule Transistor Aniruddha Chakraborty Department of Inorganic and Physical Chemistry Indian.

Introduction to Molecular Orbitals

Chemistry 6440 / 7440 Semi-Empirical Molecular Orbital Methods.

Computational Chemistry

Ivan Janeček, Daniel Hrivňák, and René Kalus Department of Physics, University of Ostrava, Ostrava, Czech Republic Supported by the Grant Agency of the.

Praha Ostrava Abstract Ab initio calculations Potential energy surface fit Outlooks Financial support: the Ministry of Education, Youth, and Sports of.

Potensial Energy Surface Pertemuan V. Definition Femtosecond spectroscopy experiments show that molecules vibrate in many different directions until an.

20_01fig_PChem.jpg Hydrogen Atom M m r Potential Energy + Kinetic Energy R C.

CHEMISTRY 2000 Topic #1: Bonding – What Holds Atoms Together? Spring 2010 Dr. Susan Lait.

Thermodynamics of rare-gas cluster cations. Aleš Vítek, Daniel Hrivňák, René Kalus Department of Physics, University of Ostrava, Ostrava, Czech Republic.

Ab Initio Calculations of the Ground Electronic States of the C 3 Ar and C 3 Ne Complexes Yi-Ren Chen, Yi-Jen Wang, and Yen-Chu Hsu Institute of Atomic.

Three-body Interactions in Rare Gases. René Kalus, František Karlický, Michal F. Jadavan Department of Physics, University of Ostrava, Ostrava, Czech Republic.

Progress Towards the Accurate Calculation of Anharmonic Vibrational States of Fluxional Molecules and Clusters Without a Potential Energy Surface Andrew.

RESULTS I: Comparison for the different rare-gases Xenon SO constant = eV E( 2 P 1/2 ) – E( 2 P 3/2 ) = eV D 0 (Xe 3 + ) = eV 1 Experiment:

Water clusters observed by chirped-pulse rotational spectroscopy: Structures and hydrogen bonding Cristobal Perez, Matt T. Muckle, Daniel P. Zaleski, Nathan.

Theoretical Study of Charge Transfer in Ion- Molecule Collisions Emese Rozsályi University of Debrecen Department of Theoretical Physics.

Daniel Hrivňák a, Karel Oleksy a, René Kalus a a Department of Physics, University of Ostrava, Ostrava, Czech Republic Financial support: the Grant Agency.

Model Chemistries Lecture CompChem 4 Chemistry 347 Hope College.

Dynamics of excited rare gas cluster cations Ivan Janeček, Daniel Hrivňák, and René Kalus Department of Physics, University of Ostrava, Ostrava, Czech.

Structural changes in rare-gas cluster cations. Aleš Vítek, František Karlický, René Kalus Department of Physics, University of Ostrava, Ostrava, Czech.

Daniel Hrivňák, Ivan Janeček and René Kalus Department of Physics, University of Ostrava, Ostrava, Czech Republic Supported by the Grant Agency of the.

© Alejandro Strachan – Binding Curves for H2 and He2 Online simulations via nanoHUB: Binding curves for H 2 molecule In this tutorial: Density functional.

The Materials Computation Center, University of Illinois Duane Johnson and Richard Martin (PIs), NSF DMR OBJECTIVE: To accelerate.

Chemistry 700 Lectures. Resources Grant and Richards, Foresman and Frisch, Exploring Chemistry with Electronic Structure Methods (Gaussian Inc., 1996)

Int. Symp. Molecular Spectroscopy Ohio State Univ., 2005 The Ground State Four Dimensional Morphed Potentials of HBr and HI Dimers Collaborator: J. W.

LITERATURE SEARCH ASSIGNMENT A) Properties of diatomic molecules A diatomic molecule is a molecule composed of two atoms. For homonuclear diatomics the.

ENERGY LEVELS OF THE NITRATE RADICAL BELOW 2000 CM -1 Christopher S. Simmons, Takatoshi Ichino and John F. Stanton Molecular Spectroscopy Symposium, June.

Computational Studies of the Electronic Spectra of Transition-Metal-Containing Molecules James T. Muckerman, Zhong Wang, Trevor J. Sears Chemistry Department,

1 HOONO ISOMERIZATION TO HONO 2 INVOLVING CONICAL INTERSECTIONS T. J. DHILIP KUMAR, and JOHN R. BARKER Department of Atmospheric, Oceanic and Space Sciences,

Materials Process Design and Control Laboratory ON THE DEVELOPMENT OF WEIGHTED MANY- BODY EXPANSIONS USING AB-INITIO CALCULATIONS FOR PREDICTING STABLE.

ChE 452 Lecture 21 Potential Energy Surfaces 1. Last Time Collision Theory Assumes reactions occur whenever reactants collide Key equations 2.

Daniel Hrivňák a, František Karlický a, Ivan Janeček a, Ivana Paidarová b, and René Kalus a a Department of Physics, University of Ostrava, Ostrava, Czech.

Advanced methods of molecular dynamics 1.Monte Carlo methods 2.Free energy calculations 3.Ab initio molecular dynamics 4.Quantum molecular dynamics 5.Trajectory.

A New Potential Energy Surface for N 2 O-He, and PIMC Simulations Probing Infrared Spectra and Superfluidity How precise need the PES and simulations be?

Petr Kašpar, Ondřej Santolík, and Ivana Kolmašová

Example: Fragmentation of argon tetramer after sudden ionisation

Professor : Ourida OUAMERALI

Semiempirical modelling of helium cluster cations

A Tale of Two Controversies

Department of Chemistry

Introduction to Tight-Binding

Ab initio Electronic and Rovibrational Structure of Fulminic Acid

Automated construction of Potential Energy

Curtin University, Perth, Australia

William D. Tuttle, Rebecca L. Thorington, Larry A

SIMULATIONS OF VIBRONIC LEVELS IN DEGENERATE ELECTRONIC STATES IN THE PRESENCE OF JAHN-TELLER COUPLING – EXPANSION OF PES THROUGH THIRD ORDER VADIM L.

First steps towards modelling three - body effects in Krn+

M. Rezaei, J. George, L. Welbanks, and N. Moazzen-Ahmadi

3-Dimensional Intermolecular Potential Energy Surface of Ar-SH(2Pi)

Efficient Sampling of Quantum Systems Using Path Integral Molecular Dynamics: Application to Weakly Bound Systems r θ Christopher Ing, Konrad Hinsen*,

Maria Okuniewski Nuclear Engineering Dept.

International Symposium on Molecular Spectroscopy

Variation of CH Stretch Frequencies with CH4 Orientation in the CH4--F- Complex: Multiple Resonances as Vibrational Conical Intersections Bishnu P Thapaliya,

Yi-Ren Chen and Yen-Chu Hsu Institute of Atomic and Molecular Sciences

Single Vibronic Level (SVL) emission spectroscopy of CHBr: Vibrational structure of the X1A and a3A  states.

The Three-dimensional Potential Energy

Lan Cheng Department of Chemistry Johns Hopkins University

Electronic bands of ScC in the region 620 – 720 nm

From Electronic Structure Theory to Simulating Electronic Spectroscopy

A Theoretical Search for an Electronic Spectrum of the He–BeO Complex

Wafaa Fawzy Murray State University (MSU)

Density Functional Resonance Theory of Metastable Negative Ions

Sara E. Ray and Anne B. McCoy

Modelling of singly ionized rare-gas clusters Daniel Hrivňák, František Karlický, and René Kalus Department.

Presentation transcript:

Ab initio calculation on He3+ of interest for semiempirical modelling of Hen+ Ivana Paidarová a), Rudolf Polák a), František Karlický b), Daniel Hrivňák b), and René Kalus b) a) J. Heyrovský Institute of Physical Chemistry, Praha, b) University of Ostrava, Ostrava Aim The principal aim of the present calculations is to provide highly accurate potential energy surfaces (PES) for the electronic ground state and the first two excited states of the He3+ ion to be employed in subsequent semiempirical modellings of larger helium cluster cations, Hen+. It is well known that the diatomics-in-molecule (DIM) approach, which performs well for the heavier rare gases, fails remarkably even for the smallest Hen+. It is argued that this is mainly due to the neglect of three-body interactions [1] within the DIM framework and, consequently, the three-body contributions to the Hen+ interaction energy have to be extracted from ab initio calculations and included in semiemirical models for them to become acceptably accurate. This can be done, e. g., within the triatomics-in-molecules (TRIM) approach [2], which represents a natural generalization of the DIM method. [1] P.J. Knowles, J.N. Murrell, E.J. Hodge, Mol. Phys. 85, 243 (1995) [2] this poster session, D. Hrivňák et al., Semiempirical modelling of Hen+ clusters. Economy calculations Computational method Equation-Of-Motion Coupled Clusters [4] basis set d-aug-cc-pVTZ [5] program package ACES II [4] J.F. Stanton and R.J. Bartlett, J. Chem. Phys. 98, 7029 (1993) [5] Basis set converged results were obtained with daug-cc-pVTZ basis set, in the series of aug-cc-pVXZ calculations, X=D,T,Q. Results Comparison of potential energy curves for the first three electronic states and for selected C2v geometries with the benchmark results ● – economy calculations ○ – benchmark calculations subplots – a detailed view of local minimum Differences between the economy and benchmark calculations for two selected geometries (C2v and D∞h) A detailed plot of the C∞v PES for the electronic ground state The C∞v PES is extremely flat for the electronic ground state Potential energy surface Computational Coordinates where r1 ≤ r2 ≤ r3 are inter-atomic distances. Analytical formula Computationally cheap Morse potential (Easymp → 0) with (X = D, A, R) Configurations ○ - anticipated three-body configurations in Hen+ clusters (n ≤ 13) ● - configurations included in fitting procedure Least-square fits rough optimization: genetic algorithm (with binary encoded strings) fine-tuning: Levenberg-Marquardt Newton-Raphson (program by V. Špirko) Results Examples of 1D fits for a representative set of geometries and for the electronic ground state ● - ab initio points from economy calculations —— - least-square fits subplots - deviations of the least-square fits from the ab initio data Distribution of the least-square fits residues for electronic ground state points Dependence of the Morse potential parameters on He3+ shape (electronic ground state) Benchmark calculations Computational method CASSCF(5,10) / icMRCI (5 active electrons in 10 active orbitals) [3] basis set d-aug-cc-pVTZ program package MOLPRO 2000.1 [3] H.-J. Werner and P. J. Knowles, J. Chem. Phys. 89, 5803 (1988); P. J. Knowles and H.-J. Werner, Chem. Phys. Letters 145, 514 (1988) Results Potential energy curves for the electronic ground state and the first two excited states calculated for C2v geometries ○ – our calculations + – M. F. Satterwhite and G. I. Gellene, J. Phys. Chem. 99, 1339 (1995) subplots – comparison with literatura data Potential energy surfaces for C2v geometries A detailed plot of the C2v PES for the electronic ground state Equilibrium structure of He3+ (comparison with literature) method Emin Re De [hartree] [bohr] [eV] QICSD(T), aug-cc-pVTZ [6] -7.896672 2.340 2.598 QICSD(T), aug-cc-pVQZ [6] -7.902103 2.336 2.640 MRD-CI, cc-pVTZ [7] -7.8954 2.34 2.59 this work, benchmark -7.897021 2.339 2.639 this work, economy -7.896084 2.341 2.639 (?) [6] M. F. Satterwhite and G. I. Gellene, J. Phys. Chem. 99, 1339 (1995) [7] E. Buonomo et al., Chem. Phys. Letters 259, 641 (1996) Grant No. 203/06/XXXX (submitted) of the Grant Agency of the Czech Republic Grant No. 203/04/2146 of the Grant Agency of the Czech Republic