Litcius/Paper detail

Interpolation Methods for Molecular Potential Energy Surface Construction

Hyuk‐Yong Kwon, Zachary Morrow, C. T. Kelley, Elena Jakubı́ková

2021The Journal of Physical Chemistry A23 citationsDOI

Abstract

The concept of a potential energy surface (PES) is one of the most important concepts in modern chemistry. A PES represents the relationship between the chemical system's energy and its geometry (i.e., atom positions) and can provide useful information about the system's chemical properties and reactivity. Construction of accurate PESs with high-level theoretical methodologies, such as density functional theory, is still challenging due to a steep increase in the computational cost with the increase of the system size. Thus, over the past few decades, many different mathematical approaches have been applied to the problem of the cost-efficient PES construction. This article serves as a short overview of interpolative methods for the PES construction, including global polynomial interpolation, trigonometric interpolation, modified Shepard interpolation, interpolative moving least-squares, and the automated PES construction derived from these.

Topics & Concepts

Interpolation (computer graphics)TrigonometryPotential energy surfaceMoving least squaresTrigonometric interpolationComputer sciencePotential energyPolynomial interpolationPolynomialSurface (topology)Applied mathematicsNearest-neighbor interpolationMultivariate interpolationMathematical optimizationAlgorithmBilinear interpolationComputational scienceSpline interpolationMathematicsGeometryChemistryPhysicsArtificial intelligenceMathematical analysisQuantum mechanicsAb initioComputer visionOrganic chemistryMotion (physics)Quantum Mechanics and Non-Hermitian PhysicsAdvanced Physical and Chemical Molecular InteractionsGraph theory and applications