01 Ausgetauschte Wärme dQ = +TdS und ausgetauschte Arbeit dW = -pdV bei (S,V;N=const)

Wärme und Arbeit sind keine Zustandänderungen, ihre Summe ist eine Zustandsänderung.

A Ausgetauschte Wärme dQ = +TdS

	$d Q$	$=$	$+ T d S$	$d Q (S, V), T (S, V, N), d N = 0$
		$=$	$+ T [+ {(\frac{\partial S}{\partial S})}_{V, N} d S + {(\frac{\partial S}{\partial V})}_{S, N} d V]$
		$=$	$+ T [+ 1 \cdot d S + 0 \cdot d V]$
$(01)$		$=$	$+ T d S + 0 d V$
		$=$	$+ d Q_{V, N} + 0$	$d Q_{V, N} (S), d Q_{S, N} (V) = 0, d N = 0$
$(02)$		$=$	$+ d U_{V, N} + 0$	$d U_{V, N} (S), d N = 0$
	${(\frac{\partial Q}{\partial S})}_{V, N}$	$=$	$+ T_{0} {(\frac{V_{0}}{V})}^{2 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) = + T$	$\partial_{S} Q (S, V, N), T (S, V, N)$
$(03)$		$=$	${(\frac{\partial U}{\partial S})}_{V, N} = + T$	$\partial_{S} U (S, V, N), T (S, V, N)$
	${(\frac{\partial Q}{\partial V})}_{S, N}$	$=$	$+ 0$	$\partial_{V} Q (S, V, N)$
$(04)$		$\neq$	${(\frac{\partial U}{\partial V})}_{S, N} = - p$	$\partial_{V} U (S, V, N), p (S, V, N)$
	$\frac{\partial}{\partial V} \frac{\partial Q}{\partial S}$	$=$	$- \frac{2}{3} \frac{T_{0}}{V} {(\frac{V_{0}}{V})}^{2 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) = - \frac{2}{3} \frac{T}{V}$	$\partial_{V} \partial_{S} Q (S, V, N), T (S, V, N)$
		$=$	$\frac{\partial}{\partial V} \frac{\partial U}{\partial S} = - \frac{2}{3} \frac{T}{V}$	$\partial_{V} \partial_{S} U (S, V, N), T (S, V, N)$
	$\frac{\partial}{\partial S} \frac{\partial Q}{\partial V}$	$=$	$+ 0$	$\partial_{S} \partial_{V} Q (S, V, N)$
		$\neq$	$\frac{\partial}{\partial S} \frac{\partial U}{\partial V} = - \frac{2}{3} \frac{p}{n R}$	$\partial_{S} \partial_{V} U (S, V, N), p (S, V, N)$
$(05)$	$\frac{\partial}{\partial V} \frac{\partial Q}{\partial S}$	$\neq$	$\frac{\partial}{\partial S} \frac{\partial Q}{\partial V}$	$\partial_{V} \partial_{S} Q (S, V, N), \partial_{S} \partial_{V} Q (S, V, N)$
	$Q_{B} (S, V, N)$	$=$	$+ \int_{S, d V = 0} T d S$	$d S (S), d V = 0, d N = 0, T (S, V, N)$
		$=$	$+ \int_{S, d V = 0} T_{0} {(\frac{V_{0}}{V})}^{2 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) d S$
		$=$	$+ \frac{3}{2} n R T_{0} {(\frac{V_{0}}{V})}^{2 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) + B (V, N)$
		$=$	$+ \frac{3}{2} n R T (S, V, N) + B (V, N)$
	$Q_{A} (S, V, N)$	$=$	$+ \int_{V, d S = 0} T d S$	$d S (V), d S = 0, d N = 0, T (S, V, N)$
		$=$	$0 + A (S, N)$
	$A$	$\neq$	$A (S, N)$	$A = const$
	$B$	$\neq$	$B (V, N)$	$B = const$
	$Q_{B} (S, V, N)$	$=$	$+ \frac{3}{2} n R T_{0} {(\frac{V_{0}}{V})}^{2 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) + B$
	$Q_{A} (S, V, N)$	$=$	$+ A$	$Q_{A} (S, V, N) = const$
	$Q_{B} (S, V, N)$	$\neq$	$Q_{A} (S, V, N)$
	$Q_{V, N} (S_{2}, S_{1})$	$=$	$Q (S_{2}, V, N) - Q (S_{1}, V, N)$
		$=$	$+ \int_{S_{1}, V}^{S_{2}, V} T d S$	$d S (S), d V = 0, d N = 0, T (S, V, N)$
$(06)$		$=$	$+ \frac{3}{2} n R T_{0} {(\frac{V_{0}}{V})}^{2 / 3} [\exp (\frac{2}{3} \frac{S_{2}}{n R}) - \exp (\frac{2}{3} \frac{S_{1}}{n R})]$
		$=$	$U (S_{2}, V, N) - U (S_{1}, V, N)$
$(07)$		$=$	$U_{V, N} (S_{2}, S_{1})$
	$Q_{S, N} (V_{2}, V_{1})$	$=$	$Q (S, V_{2}, N) - Q (S, V_{1}, N)$
		$=$	$+ \int_{V_{1}, S}^{V_{2}, S} T d S$	$d S (V), d S = 0, d N = 0, T (S, V, N)$
$(08)$		$=$	$0$

B Ausgetauschte Arbeit dW = -pdV

	$d W$	$=$	$- p d V$	$d W (S, V), p (S, V, N), d N = 0$
		$=$	$- p [+ {(\frac{\partial V}{\partial S})}_{V, N} d S + {(\frac{\partial V}{\partial V})}_{S, N} d V]$
		$=$	$- p [+ 0 \cdot d S + 1 \cdot d V]$
$(01)$		$=$	$- 0 d S - p d V$
		$=$	$+ 0 + d W_{S, N}$	$d W_{V, N} (S) = 0, d W_{S, N} (V), d N = 0$
$(02)$		$=$	$+ 0 + d U_{S, N}$	$d U_{S, N} (V), d N = 0$
	${(\frac{\partial W}{\partial S})}_{V, N}$	$=$	$- 0$	$\partial_{S} W (S, V, N)$
$(03)$		$\neq$	${(\frac{\partial U}{\partial S})}_{V, N} = + T$	$\partial_{S} U (S, V, N), T (S, V, N)$
	${(\frac{\partial W}{\partial V})}_{S, N}$	$=$	$- p_{0} {(\frac{V_{0}}{V})}^{5 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) = - p$	$\partial_{V} W (S, V, N), p (S, V, N)$
$(04)$		$=$	${(\frac{\partial U}{\partial V})}_{S, N} = - p$	$\partial_{V} U (S, V, N), p (S, V, N)$
	$\frac{\partial}{\partial V} \frac{\partial W}{\partial S}$	$=$	$- 0$	$\partial_{V} \partial_{S} W (S, V, N)$
		$\neq$	$\frac{\partial}{\partial V} \frac{\partial U}{\partial S} = - \frac{2}{3} \frac{T}{V}$	$\partial_{V} \partial_{S} U (S, V, N), T (S, V, N)$
	$\frac{\partial}{\partial S} \frac{\partial W}{\partial V}$	$=$	$- \frac{2}{3} \frac{p_{0}}{n R} {(\frac{V_{0}}{V})}^{5 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) = - \frac{2}{3} \frac{p}{n R}$	$\partial_{S} \partial_{V} W (S, V, N), p (S, V, N)$
		$=$	$\frac{\partial}{\partial S} \frac{\partial U}{\partial V} = - \frac{2}{3} \frac{p}{n R}$	$\partial_{S} \partial_{V} U (S, V, N), p (S, V, N)$
$(05)$	$\frac{\partial}{\partial V} \frac{\partial W}{\partial S}$	$\neq$	$\frac{\partial}{\partial S} \frac{\partial W}{\partial V}$	$\partial_{V} \partial_{S} W (S, V, N), \partial_{S} \partial_{V} W (S, V, N)$
	$W_{B} (S, V, N)$	$=$	$- \int_{S, d V = 0} p d V$	$d V (S), d V = 0, d N = 0, p (S, V, N)$
		$=$	$- 0 + B (V, N)$
	$W_{A} (S, V, N)$	$=$	$- \int_{V, d S = 0} p d V$	$d V (V), d S = 0, d N = 0, p (S, V, N)$
		$=$	$- \int_{V, d S = 0} p_{0} {(\frac{V_{0}}{V})}^{5 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) d V$
		$=$	$+ \frac{3}{2} V p_{0} {(\frac{V_{0}}{V})}^{5 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) + A (S, N)$
		$=$	$+ \frac{3}{2} V p (S, V, N) + A (S, N)$
		$=$	$+ \frac{3}{2} p_{0} V_{0} {(\frac{V_{0}}{V})}^{2 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) + A (S, N)$
		$=$	$+ \frac{3}{2} n R T_{0} {(\frac{V_{0}}{V})}^{2 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) + A (S, N)$
		$=$	$+ \frac{3}{2} n R T (S, V, N) + A (S, N)$
	$A$	$\neq$	$A (S, N)$	$A = const$
	$B$	$\neq$	$B (V, N)$	$B = const$
	$W_{B} (S, V, N)$	$=$	$+ B$	$W_{B} (S, V, N) = const$
	$W_{A} (S, V, N)$	$=$	$+ \frac{3}{2} n R T_{0} {(\frac{V_{0}}{V})}^{2 / 3} \exp (\frac{2}{3} \frac{S - S_{0}}{n R}) + A$
	$W_{B} (S, V, N)$	$\neq$	$W_{A} (S, V, N)$
	$W_{V, N} (S_{2}, S_{1})$	$=$	$W (S_{2}, V, N) - W (S_{1}, V, N)$
		$=$	$- \int_{S_{1}, V}^{S_{2}, V} p d V$	$d V (S), d V = 0, d N = 0, p (S, V, N)$
$(06)$		$=$	$0$
	$W_{S, N} (V_{2}, V_{1})$	$=$	$W (S, V_{2}, N) - W (S, V_{1}, N)$
		$=$	$- \int_{V_{1}, S}^{V_{2}, S} p d V$	$d V (V), d S = 0, d N = 0, p (S, V, N)$
$(07)$		$=$	$+ \frac{3}{2} n R T_{0} [{(\frac{V_{0}}{V_{2}})}^{2 / 3} - {(\frac{V_{0}}{V_{1}})}^{2 / 3}] \exp (\frac{2}{3} \frac{S - S_{0}}{n R})$
		$=$	$U (S, V_{2}, N) - U (S, V_{1}, N)$
$(08)$		$=$	$U_{S, N} (V_{2}, V_{1})$

PCRT.I.E.01

01 Ausgetauschte Wärme dQ = +TdS und ausgetauschte Arbeit dW = -pdV bei (S,V;N=const)

A Ausgetauschte Wärme dQ = +TdS

B Ausgetauschte Arbeit dW = -pdV

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PCRT.I.E.01

01 Ausgetauschte Wärme dQ = +TdS und ausgetauschte Arbeit dW = -pdV bei (S,V;N=const)

A Ausgetauschte Wärme dQ = +TdS

B Ausgetauschte Arbeit dW = -pdV

Navigationsmenü

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