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An efficient extrapolation to the (T)/CBS limit.

Duminda S Ranasinghe1, Ericka C Barnes2

  • 1Hall-Atwater Laboratories of Chemistry, Wesleyan University, Middletown, Connecticut 06459-0180, USA.

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|May 17, 2014
PubMed
Summary
This summary is machine-generated.

New Wesleyan-1-Triples basis sets (Wes1T-2Z and Wes1T-3Z) efficiently extrapolate to the (T)/complete basis set limit. These cost-effective calculations achieve accuracy comparable to benchmark methods for diverse chemical species.

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Area of Science:

  • Quantum Chemistry
  • Computational Chemistry
  • Theoretical Chemistry

Background:

  • Accurate prediction of molecular energies is crucial for chemical research.
  • Extrapolation to the (T)/complete basis set (CBS) limit is a standard, yet computationally intensive, method.
  • Development of efficient basis sets is needed to reduce computational cost.

Purpose of the Study:

  • To introduce and validate new double-zeta (Wes1T-2Z) and triple-zeta (Wes1T-3Z) basis sets for extrapolating to the (T)/CBS limit.
  • To assess the accuracy and cost-effectiveness of the new Wes1T-(2,3)Z extrapolation method.
  • To provide a more efficient approach for calculating the (T) component in composite model chemistries.

Main Methods:

  • Optimization of Wes1T-2Z and Wes1T-3Z basis sets for 102 chemical species across the first two rows of the Periodic Table.
  • Extrapolation of perturbative triples (T) energies to the complete basis set (CBS) limit using the new basis sets.
  • Comparison of Wes1T-(2,3)Z results with established benchmark (T)/CBS values and other model chemistries (W1, CBS-APNO, CBS-QB3).

Main Results:

  • The extrapolated Wes1T-(2,3)Z triples energies show excellent agreement with (T)/CBS benchmarks (within ±0.65 mEh).
  • The Wes1T-(2,3)Z method demonstrates significantly improved cost-effectiveness, with calculation times reduced by a factor of 25 compared to W1 for large systems.
  • RMS deviations for Wes1T-(2,3)Z are competitive, with notable improvement over CBS-APNO and CBS-QB3.

Conclusions:

  • The Wes1T-2Z and Wes1T-3Z basis sets provide a computationally efficient and accurate route for extrapolating to the (T)/CBS limit.
  • The developed Wes1T-(2,3)Z extrapolation method is a valuable tool for theoretical chemistry, enabling more accessible high-accuracy energy calculations.
  • These basis sets facilitate the efficient calculation of the (T) component in various composite model chemistries.