Potential-energy functions

That is, a molecule for which the minimum of the Born-Oppenheimer potential energy function corresponds to a... 

Statistical mechanical theory and computer simulations provide a link between the equation of state and the interatomic potential energy functions. A fluid-solid transition at high density has been inferred from computer simulations of hard spheres. A vapour-liquid phase transition also appears when an attractive component is present hr the interatomic potential (e.g. atoms interacting tlirough a Leimard-Jones potential) provided the temperature lies below T, the critical temperature for this transition. This is illustrated in figure A2.3.2 where the critical point is a point of inflexion of tire critical isothemr in the P - Vplane. 

Consider a polyatomic system consisting of N nuclei (where > 3) and elecbons. In the absence of any external fields, we can rigorously separate the motion of the center of mass G of the whole system as its potential energy function V is independent of the position vector of G (rg) in a laboratory-fixed frame with origin O. This separation introduces, besides rg, the Jacobi vectors R = (R , , R , .. , Rxk -1) = (fi I "21 I fvji) fot nuclei and electrons,... 

The potential matrix elements are then obtained by making Taylor expansions around 00, using suitable zero-order diabatic potential energy functions,... 

Both the BO dynamics and Gaussian wavepacket methods described above in Section n separate the nuclear and electronic motion at the outset, and use the concept of potential energy surfaces. In what is generally known as the Ehrenfest dynamics method, the picture is still of semiclassical nuclei and quantum mechanical electrons, but in a fundamentally different approach the electronic wave function is propagated at the same time as the pseudoparticles. These are driven by standard classical equations of motion, with the force provided by an instantaneous potential energy function... 

J. N, Murrell, S. Carter, S. C. Farancos, P. Huxley, and A. J, C. Varandas, Molecular Potential Energy Functions, John Wiley Sons, Tnc., Chichester, 1984. 

The basic idea of NMA is to expand the potential energy function U(x) in a Taylor series expansion around a point Xq where the gradient of the potential vanishes ([Case 1996]). If third and higher-order derivatives are ignored, the dynamics of the system can be described in terms of the normal mode directions and frequencies Qj and Ui which satisfy ... 

Amadei et al. 1993] Amadei, A., Linssen, A.B.M., Berendsen, H.J.C. Essential Dynamics of Proteins. Proteins 17 (1993) 412-425 [Balsera et al. 1997] Balsera, M., Stepaniants, S., Izrailev, S., Oono, Y., Schiilten, K. Reconstructing Potential Energy Functions from Simulated Force-Induced Unbinding Processes. Biophys. J. 73 (1997) 1281-1287 [Case 1996] Case, D.A. Normal mode analysis of protein dynamics. Curr. Op. Struct. Biol. 4 (1994) 285-290... 

Balsera, M., Stepaniants, S., Izrailev, S., Oono, Y., Schulten, K. Reconstructing potential energy functions from simulated force-induced unbinding processes. Biophys. J. 73 (1997) 1281-1287... 

A potential advantage of methods based on a series expansion of the free energy is that the convergence of the series is determined by the A dependence of the potential energy function meaning that the efficiency of the approach could be enhanced by a judicious choice of coupling scheme. 

Fig. 3. Curves calculated using (8) for a series of increasing a values. The curves were calculated using tr = 0.6 nm and e = 0.4 kj/mol. Note that for a = 0.0 the normal 6-12 Lennard Jones potential energy function is recovered.

For a given potential energy function U r ), the corresponding generalized statistical probability distribution which is generated by the Monte Carlo algorithm is proportional to... 

T. Schlick and M. L. Overton. A powerful truncated Newton method for potential energy functions. J. Comp. Chem., 8 1025-1039, 1987. 

For a given potential energy function, one may take a variety of approaches to study the dynamics of macromolecules. The most exact and detailed information is provided by MD simulations in which one solves the equations of motion for the atoms constituting the macromolecule and any surrounding environment. With currently available techniques and methods it is possible... 

Molecular dynamics conceptually involves two phases, namely, the force calculations and the numerical integration of the equations of motion. In the first phase, force interactions among particles based on the negative gradient of the potential energy function U,... 

Figure 2-108. Derivation of a syrMbolic potential energy function from the torsion angle distribution of a torsion fragment.

To see the contributions to the molecular mechanics potential energy function and their mathematical representation... 

Figure 7-8. Bonded (upper row) and non-bonded (lower row) contributions to a typioal molecular mechanics force field potential energy function. The latter two types of Interactions can also occur within the same molecule.

The mathematical formulation of a typical molecular mechanics force field, which is also called the potential energy function (PEF), is shown in Eq. (18). Do not wony yet about the necessary mathematical expressions - they will be explained in detail in the following sections ... 

Spedal emphasis was placed on the calculation of spectroscopic properties and properties of distorted molecules. The potential energy function of CFF is domi-... 

How can we apply molecular dynamics simulations practically. This section gives a brief outline of a typical MD scenario. Imagine that you are interested in the response of a protein to changes in the amino add sequence, i.e., to point mutations. In this case, it is appropriate to divide the analysis into a static and a dynamic part. What we need first is a reference system, because it is advisable to base the interpretation of the calculated data on changes compared with other simulations. By taking this relative point of view, one hopes that possible errors introduced due to the assumptions and simplifications within the potential energy function may cancel out. All kinds of simulations, analyses, etc., should always be carried out for the reference and the model systems, applying the same simulation protocols. 

A Fortran90 library for the simulation of molecular systems using molecular mechanics (MM) and hybrid quantum mechanics/molecular mechanics (QM)/ MM) potential energy functions. http //www.ibs.fr/ext/labos/LDM/projet6/... 

Molecular Mechanic use an aiialyLical, dil fereiiliable, aiui relatively simple potential energy function, -(R). for describing the inieraciions between a set of atoms specified by their Cartesian coordinates R. 

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