Master equation: Difference between revisions

Latest revision as of 11:07, 1 July 2008

The master equation describes the exact behavior of the velocity distribution for any time (Ref. 1 Eq. 3-11)

\partial _{t\rho _{0}}\left(\{{\mathbf {\upsilon } }\},t\right)={\mathcal {D}}_{0}\left(t,\rho _{\{k''\}}\left(\{{\mathbf {\upsilon } }\},0\right)\right)+\int _{0}^{t}G_{00}(t-t')\rho _{0}\left(\{{\upsilon }\},t'\right){\mathrm {d} }t'

where the time dependent functional of the initial conditions is given by (Ref. 1 Eq. 3-9)

{\mathcal {D}}_{0}\left(t,\rho _{\{k''\}}\left(\{{\mathbf {\upsilon } }\},0\right)\right)={\frac {-1}{2\pi }}\oint _{c}\exp(-izt)\sum _{\{k''\}\neq 0}{\mathcal {D}}_{0\{k''\}}^{+}(z)\rho _{\{k''\}}\left(\{{\mathbf {\upsilon } }\},0\right)

and the diagonal fragment is given by (Ref. 1 Eq. 3-10)

G_{00}(\tau )={\frac {1}{2\pi i}}\oint _{c}\exp(-iz\tau )\psi _{00}^{+}(z)~{\mathrm {d} }z

The equations of evolution for the distribution function $\rho$ for the diagonal fragments(Ref. 1 Eq. 3-1)

\psi _{\{k\}\{k\}}(z)=\sum _{n=2}^{\infty }(-\lambda )^{n}\langle \{k\}\vert \delta L\left[{\frac {1}{L_{0}-z}}\delta L\right]^{n}\vert \{k\}\rangle

for the creation fragments (Ref. 1 Eq. 3-2)

{\tilde {C}}_{\{k\}\{k'\}}(z)=\sum _{n=1}^{\infty }(-\lambda )^{n}\langle \{k\}\vert \left[{\frac {1}{L_{0}-z}}\delta L\right]^{n}\vert \{k'\}\rangle

and for the destruction regions (Ref. 1 Eq. 3-3)

{\mathcal {D}}_{\{k'\}\{k''\}}(z)=\sum _{n=1}^{\infty }(-\lambda )^{n}\langle \{k'\}\vert \left[\delta L{\frac {1}{L_{0}-z}}\right]^{n}\vert \{k''\}\rangle

@@ Line 11: / Line 11: @@
 :<math>G_{00}(\tau)  = \frac{1}{2\pi i} \oint_c \exp (-iz \tau) \psi^+_{00} (z)~ {\mathrm d}z </math>
+==Equations of evolution==
+The equations of evolution for the distribution function <math>\rho</math> for the diagonal fragments(Ref. 1 Eq. 3-1)
+:<math>\psi_{ \{k\}\{k\}}(z) = \sum_{n=2}^\infty (-\lambda)^n \langle \{k\}  \vert \delta L \left[ \frac{1}{L_0-z} \delta L \right]^n  \vert \{k\} \rangle </math>
+for the creation fragments (Ref. 1 Eq. 3-2)
+:<math>\tilde{C}_{ \{k\}\{k'\}}(z) = \sum_{n=1}^\infty (-\lambda)^n \langle \{k\}  \vert  \left[ \frac{1}{L_0-z} \delta L \right]^n  \vert \{k'\} \rangle </math>
+and for the destruction regions (Ref. 1 Eq. 3-3)
+:<math>\mathcal{D}_{ \{k'\}\{k''\}}(z) = \sum_{n=1}^\infty (-\lambda)^n \langle \{k'\}  \vert  \left[ \delta L \frac{1}{L_0-z}  \right]^n  \vert \{k''\} \rangle </math>
 ==References==
-#[http://dx.doi.org/10.1016/0031-8914(61)90008-8 I. Prigonine and P. Résibois "On the kinetics of the approach to equilibrium", Physica '''27''' pp. 629-646  (1961)]
+#[http://dx.doi.org/10.1016/0031-8914(61)90008-8 I. Prigogine and P. Résibois "On the kinetics of the approach to equilibrium", Physica '''27''' pp. 629-646  (1961)]
 [[category: Non-equilibrium thermodynamics]]