【12.07】避难所临时餐会

\frac{\mathrm d\Gamma}{\mathrm d t}=\oint_L \frac{\mathrm d \vec{V}}{\mathrm dt}\cdot \delta l= \oint \vec{F}\cdot \delta l-\oint_l\frac{1}{\rho}\nabla p\delta b-\nu\oint_l\nabla\times\xi\delta l

\therefore\oint\vec{F}\cdot \delta l=0,\\ v\oint\nabla\times\xi\delta l=0\\ \therefore \frac{\mathrm d \Gamma}{\mathrm dt}=-\oint_l\frac{1}{\rho}\nabla p\delta l\\ 又\because \alpha=\frac1\rho, \nabla\cdot\delta l=\mathrm d p\\ \therefore \frac{\mathrm d \Gamma}{\mathrm dt}=-\oint\alpha \mathrm d p\\

\therefore \frac1\alpha=\frac{RT}{p},\\ \therefore \frac{\mathrm d \Gamma}{\mathrm dt}=-\oint \frac{R_dT}{p}\mathrm dp=R_d\delta \bar{T}\ln\frac{p}{p-\delta p}≈R_d\delta \bar{T}\ln\frac{\delta p}{p}

\oint_S\vec{D}\cdot\mathrm d\vec{S}=\sum q=\int_V\rho\mathrm dV\\ \oint\vec{E}\cdot\mathrm d\vec{l}=-\int_S\frac{\partial\vec{B}}{\partial{t}}\cdot\mathrm dS\\ \oint_S\vec{B}\cdot\mathrm d\vec{S}=0\\ \oint_L\vec{H}\cdot\mathrm d\vec{l}=\int_S\vec{j}\cdot\mathrm d\vec{S}+\int_S\frac{\partial\vec{D}}{\partial t}\cdot\mathrm d \vec{S}