John M. Heck scite author profile

John M. Heck

2Publications

61Citation Statements Received

20Citation Statements Given

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The Ohio State University

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Fit of the potential energy surface for the reaction Ne+H2+→NeH++H using three different functional forms

Pendergast

Heck

Hayes

et al. 1993

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Articles you may be interested inCross sections and rate constants for OH + H2 reaction on three different potential energy surfaces for rovibrationally excited reagents J. Chem. Phys. 135, 194302 (2011); 10.1063/1.3660222 Predicting observables on different potential energy surfaces using feature sensitivity analysis: Application to the collinear H+H2 exchange reaction J. Chem. Phys. 97, 6240 (1992); 10.1063/1.463685 Distributed complex Gaussian basis sets: A useful function space for the solution of predissociation problems via the complex eigenvalue Schrödinger equation. Application to the isotope effect of NeH, NeD J. Chem. Phys. 93, 6642 (1990); 10.1063/1.458932 Potential energy surface for the collinear reaction of Ne and HeHThree different functional forms are fit to a calculated coupled electron pair approach potential energy surface for the reaction Ne+Ht ..... NeH+ +H. Minimum energy pathways and stationary points of the various fits are discussed.represents the H-H distance.

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A comparative basis‐set study of NeH⁺ using coupled‐cluster techniques

Pendergast

Heck

Hayes

1994

Int J of Quantum Chemistry

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Unrestricted Hartree-Fock, coupled-cluster calculations are reported for the ground state of NeH' using atomic basis sets of increasing size and accuracy for both Ne and H. The goal is to determine the basis set and coupled-cluster level of calculation needed to obtain a NeH' potential energy curve of known accuracy. Here, it is shown that calculations using a quintuple zeta basis at the coupled-cluster singles and doubles level with noniterative triples, CCSD(T), predict a Ne-H bond dissociation energy that is within about 0.01 eV of the exact Born-Oppenheimer molecular electronic structure result. Spectroscopic constants determined using the Simons-Parr-Finlan procedure are found to be in very good agreement with the experimental results. Calculations at the augmented quadruple zeta level for the two lowest triplet excited states of the NeH' species are presented. Both of these states separate into ground-state Ne' and H(1s). The resulting potential curves predict stable minima at the SCF, CCSD, and CCSD(T) levels with dissociation energies of about 0.07 eV. Spectroscopic constants from the potential curves and dissociation constants are reported.

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John M. Heck

Fit of the potential energy surface for the reaction Ne+H2+→NeH++H using three different functional forms

A comparative basis‐set study of NeH⁺ using coupled‐cluster techniques

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John M. Heck

Fit of the potential energy surface for the reaction Ne+H2+→NeH++H using three different functional forms

A comparative basis‐set study of NeH+ using coupled‐cluster techniques

Contact Info

Product

Resources

About

A comparative basis‐set study of NeH⁺ using coupled‐cluster techniques