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Chemistry 6440 / 7440. Potential Energy Surfaces. Model Potential Energy Surface. Potential Energy Surfaces. Many aspects of chemistry can be reduced to questions about potential energy surfaces (PES) A PES displays the energy of a molecule as a function of its geometry
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Chemistry 6440 / 7440 Potential Energy Surfaces
Potential Energy Surfaces • Many aspects of chemistry can be reduced to questions about potential energy surfaces (PES) • A PES displays the energy of a molecule as a function of its geometry • Energy is plotted on the vertical axis, geometric coordinates (e.g bond lengths, valence angles, etc.) are plotted on the horizontal axes • A PES can be thought of it as a hilly landscape, with valleys, mountain passes and peaks • Real PES have many dimensions, but key feature can be represented by a 3 dimensional PES
Equilibrium molecular structures correspond to the positions of the minima in the valleys on a PES • Energetics of reactions can be calculated from the energies or altitudes of the minima for reactants and products • A reaction path connects reactants and products through a mountain pass • A transition structure is the highest point on the lowest energy path • Reaction rates can be obtained from the height and profile of the potential energy surface around the transition structure
The shape of the valley around a minimum determines the vibrational spectrum • Each electronic state of a molecule has a separate potential energy surface, and the separation between these surfaces yields the electronic spectrum • Properties of molecules such as dipole moment, polarizability, NMR shielding, etc. depend on the response of the energy to applied electric and magnetic fields
Potential Energy Surfaces and the Born-Oppenheimer Approximation • A PES associates an energy with each geometry of a molecule • Quantum mechanics can be used to calculate the energy as a function of the positions of the nuclei • This assumes that the electronic distribution of the molecule adjusts quickly to any movement of the nuclei • This corresponds to invoking the Born-Oppenheimer approximation in the solution of the Schrödinger equation for a molecular system • Except when potential energy surfaces for different states get too close to each other or cross, the Born-Oppenheimer approximation is usually quite good • Thus a PES arises as a natural consequence of the Born-Oppenheimer approximation
PES and Molecular Dynamics • A molecule in motion can be visualized as a ball rolling on a potential energy surface • Dynamics of a molecule can be treated either classically or quantum mechanically • Small amplitude motions correspond to molecular vibrations (treated quantum mechanically) • Large amplitude motions can lead to reactions (treated by classical trajectory calculations) • Statistical mechanics connects the dynamics of an individual molecule with the behavior of macroscopic samples
PES Summary • The concept of potential energy surfaces is central to computational chemistry • The structure, energetics, properties, reactivity, spectra and dynamics of molecules can be readily understood in terms of potential energy surfaces • Except in very simple cases, the potential energy surface cannot be obtained from experiment • The field of computational chemistry has developed a wide array of methods for exploring potential energy surface • The challenge for computational chemistry is to explore potential energy surfaces with methods that are efficient and accurate enough to describe the chemistry of interest
Asking the Right Questions • molecular modeling can answer some questions easier than others • stability and reactivity are not precise concepts • need to give a specific reaction • similar difficulties with other general concepts: • resonance • nucleophilicity • leaving group ability • VSEPR • etc.
Asking the Right Questions • phrase questions in terms of energy differences, energy derivatives, geometries, electron distributions • trends easier than absolute numbers • gas phase much easier than solution • structure and electron distribution easier than energetics • vibrational spectra and NMR easier than electronic spectra • bond energies, IP, EA, activation energies are hard (PA not quite as hard) • excited states much harder than ground states • solvation by polarizable continuum models (very hard by dynamics)