Rigid top propagator: Difference between revisions
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For a rigid three dimensional asymmetric top the kernel is given by (<ref>[http://dx.doi.org/10.1103/PhysRevLett.77.2638 M. H. Müser and B. J. Berne "Path-Integral Monte Carlo Scheme for Rigid Tops: Application to the Quantum Rotator Phase Transition in Solid Methane", Physical Review Letters '''77''' pp. 2638-2641 (1996)]</ref><ref>[http://dx.doi.org/10.1063/1.3544214 Eva G. Noya, Carlos Vega, and Carl McBride "A quantum propagator for path-integral simulations of rigid molecules", Journal of Chemical Physics '''134''' 054117 (2011)]</ref> | For a rigid three dimensional asymmetric top the kernel is given by (<ref>[http://dx.doi.org/10.1103/PhysRevLett.77.2638 M. H. Müser and B. J. Berne "Path-Integral Monte Carlo Scheme for Rigid Tops: Application to the Quantum Rotator Phase Transition in Solid Methane", Physical Review Letters '''77''' pp. 2638-2641 (1996)]</ref><ref>[http://dx.doi.org/10.1063/1.3544214 Eva G. Noya, Carlos Vega, and Carl McBride "A quantum propagator for path-integral simulations of rigid molecules", Journal of Chemical Physics '''134''' 054117 (2011)]</ref>) (Eq. 15) | ||
):<math> | |||
\rho_{\mathrm{rot}}^{t,t+1} (\beta/P)= | |||
\sum_{J=0}^{\infty} \sum_{M=-J}^J\sum_{\hat{K}=-J}^J | |||
\left( \frac{2J+1}{8\pi^2} \right) A_{\hat{K}M}^{(JM)} | |||
\exp \left( -\frac{\beta}{P} E_{\hat{K}}^{(JM)}\right) | |||
\sum_{K=-J}^J A_{\hat{K}K}^{(JM)} d_{MK}^J (\tilde{\theta}^{t+1}) | |||
\cos( M\tilde{\phi}^{t+1}+K\tilde{\chi}^{t+1}) | |||
</math> | |||
The contribution to the rotational energy of the interactions between beads <math>t</math> and <math>t+1</math> is given by (Eq. 16): | |||
:<math>e_{rot}^{t,t+1}= \frac{1}{ \rho_{\mathrm{rot}}^{t,t+1}} | |||
\sum_{JM\hat{K}} | |||
\left( \frac{2J+1}{8\pi^2} \right) A_{\hat{K}M}^{(JM)} E_{\hat{K}}^{(JM)} | |||
\exp \left( -\frac{\beta}{P} E_{\hat{K}}^{(JM)}\right) | |||
\sum_K A_{\hat{K}K}^{(JM)} d_{MK}^J (\tilde{\theta}^{t+1}) | |||
\cos( M\tilde{\phi}^{t+1}+K\tilde{\chi}^{t+1})</math> | |||
==References== | ==References== | ||
<references/> | <references/> | ||
;Related reading | |||
*[http://dx.doi.org/10.1016/j.cpc.2012.10.025 Carl McBride, Eva G. Noya, and Carlos Vega "A computer program to evaluate the NVM propagator for rigid asymmetric tops for use in path integral simulations of rigid bodies", Computer Physics Communications (In Press)(2012)] [http://cpc.cs.qub.ac.uk/summaries/AEOA_v1_0.html (computer code)] | |||
[[category: Quantum mechanics]] | [[category: Quantum mechanics]] | ||
Latest revision as of 11:40, 27 November 2012
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For a rigid three dimensional asymmetric top the kernel is given by ([1][2]) (Eq. 15) ):
The contribution to the rotational energy of the interactions between beads and is given by (Eq. 16):
References[edit]
- ↑ M. H. Müser and B. J. Berne "Path-Integral Monte Carlo Scheme for Rigid Tops: Application to the Quantum Rotator Phase Transition in Solid Methane", Physical Review Letters 77 pp. 2638-2641 (1996)
- ↑ Eva G. Noya, Carlos Vega, and Carl McBride "A quantum propagator for path-integral simulations of rigid molecules", Journal of Chemical Physics 134 054117 (2011)
- Related reading