Nose-Hoover-chain thermostat: Difference between revisions
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where <math>\mathcal{H}(\bold{r},\bold{p})</math> is the Hamiltonian of the physical system, <math>M</math> and <math>N</math> are the numbers of thermostats and atoms in the cell, respectively, and <math>\eta_{j}</math>, <math>p_{\eta_j}</math>, and <math>Q_{j}</math> are the position, momentum, and mass-like parameter associated with the thermostat <math>j</math>. | where <math>\mathcal{H}(\bold{r},\bold{p})</math> is the Hamiltonian of the physical system, <math>M</math> and <math>N</math> are the numbers of thermostats and atoms in the cell, respectively, and <math>\eta_{j}</math>, <math>p_{\eta_j}</math>, and <math>Q_{j}</math> are the position, momentum, and mass-like parameter associated with the thermostat <math>j</math>. Note that by setting <math>M</math>, formulation of the standard {{TAG|Nose-Hoover thermostat}} is recovered. | ||
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Revision as of 14:00, 17 April 2023
The standard Nose Hoover suffers from well known issues, such as the ergodicity violation in the case of simple harmonic oscillator. As proposed by Martyna and Klein, these problems can be solved by using multiple Nose Hoover thermostats connected in a chain. Although the underlining dynamics is non-Hamiltonian, the corresponding equations of motion conserve the following energy term:
where is the Hamiltonian of the physical system, and are the numbers of thermostats and atoms in the cell, respectively, and , , and are the position, momentum, and mass-like parameter associated with the thermostat . Note that by setting , formulation of the standard Nose-Hoover thermostat is recovered.