4: The Second Law

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 \( \newcommand{\rf}{^{\text{ref}}}     % reference state\)
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 \( \newcommand{\K}{\units{K}}  % kelvins\)
 \( \newcommand{\degC}{^\circ\text{C}} % degrees Celsius\)
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 \( \newcommand{\Pa}{\units{Pa}}\)
 \( \newcommand{\mol}{\units{mol}}  % mole\)
 \( \newcommand{\V}{\units{V}}  % volts\)
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 \( \newcommand{\per}{^{-1}}  % minus one power\)
 \( \newcommand{\m}{_{\text{m}}}  % subscript m for molar quantity\)
 \( \newcommand{\CVm}{C_{V,\text{m}}} % molar heat capacity at const.V\)
 \( \newcommand{\Cpm}{C_{p,\text{m}}} % molar heat capacity at const.p\)
 \( \newcommand{\kT}{\kappa_T} % isothermal compressibility\)
 \( \newcommand{\A}{_{\text{A}}}  % subscript A for solvent or state A\)
 \( \newcommand{\B}{_{\text{B}}}  % subscript B for solute or state B\)
 \( \newcommand{\bd}{_{\text{b}}}  % subscript b for boundary or boiling point\)
 \( \newcommand{\C}{_{\text{C}}}  % subscript C\)
 \( \newcommand{\f}{_{\text{f}}}  % subscript f for freezing point\)
 \( \newcommand{\mA}{_{\text{m},\text{A}}} % subscript m,A (m=molar)\)
 \( \newcommand{\mB}{_{\text{m},\text{B}}} % subscript m,B (m=molar)\)
 \( \newcommand{\mi}{_{\text{m},i}}        % subscript m,i (m=molar)\)
 \( \newcommand{\fA}{_{\text{f},\text{A}}} % subscript f,A (for fr. pt.)\)
 \( \newcommand{\fB}{_{\text{f},\text{B}}} % subscript f,B (for fr. pt.)\)
 \( \newcommand{\xbB}{_{x,\text{B}}}       % x basis, B\)
 \( \newcommand{\xbC}{_{x,\text{C}}}       % x basis, C\)
 \( \newcommand{\cbB}{_{c,\text{B}}}       % c basis, B\)
 \( \newcommand{\mbB}{_{m,\text{B}}}       % m basis, B\)
 \( \newcommand{\kHi}{k_{\text{H},i}}      % Henry's law constant, x basis, i\)
 \( \newcommand{\kHB}{k_{\text{H,B}}}      % Henry's law constant, x basis, B\)
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 \( \newcommand{\irr}{\subs{irr}} % irreversible\)
 \( \newcommand{\fric}{\subs{fric}} % friction\)
 \( \newcommand{\diss}{\subs{diss}} % dissipation\)
 \( \newcommand{\el}{\subs{el}} % electrical\)
 \( \newcommand{\cell}{\subs{cell}} % cell\)
 \( \newcommand{\As}{A\subs{s}} % surface area\)
 \( \newcommand{\E}{^\mathsf{E}} % excess quantity (superscript)\)
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 \( \newcommand{\liquid}{\tx{(l)}}\)
 \( \newcommand{\gas}{\tx{(g)}}\)
 \( \newcommand{\pha}{\alpha}        % phase alpha\)
 \( \newcommand{\phb}{\beta}         % phase beta\)
 \( \newcommand{\phg}{\gamma}        % phase gamma\)
 \( \newcommand{\aph}{^{\alpha}}     % alpha phase superscript\)
 \( \newcommand{\bph}{^{\beta}}      % beta phase superscript\)
 \( \newcommand{\gph}{^{\gamma}}     % gamma phase superscript\)
 \( \newcommand{\aphp}{^{\alpha'}}   % alpha prime phase superscript\)
 \( \newcommand{\bphp}{^{\beta'}}    % beta prime phase superscript\)
 \( \newcommand{\gphp}{^{\gamma'}}   % gamma prime phase superscript\)
 \( \newcommand{\apht}{\small\aph} % alpha phase tiny superscript\)
 \( \newcommand{\bpht}{\small\bph} % beta phase tiny superscript\)
 \( \newcommand{\gpht}{\small\gph} % gamma phase tiny superscript\)

\( \newcommand{\upOmega}{\Omega}\)

 \( \newcommand{\dif}{\mathop{}\!\mathrm{d}}   % roman d in math mode, preceded by space\)
 \( \newcommand{\Dif}{\mathop{}\!\mathrm{D}}   % roman D in math mode, preceded by space\)
 \( \newcommand{\df}{\dif\hspace{0.05em} f} % df\)

 \(\newcommand{\dBar}{\mathop{}\!\mathrm{d}\hspace-.3em\raise1.05ex{\Rule{.8ex}{.125ex}{0ex}}} % inexact differential \)
 \( \newcommand{\dq}{\dBar q} % heat differential\)
 \( \newcommand{\dw}{\dBar w} % work differential\)
 \( \newcommand{\dQ}{\dBar Q} % infinitesimal charge\)
 \( \newcommand{\dx}{\dif\hspace{0.05em} x} % dx\)
 \( \newcommand{\dt}{\dif\hspace{0.05em} t} % dt\)
 \( \newcommand{\difp}{\dif\hspace{0.05em} p} % dp\)
 \( \newcommand{\Del}{\Delta}\)
 \( \newcommand{\Delsub}[1]{\Delta_{\text{#1}}}\)
 \( \newcommand{\pd}[3]{(\partial #1 / \partial #2 )_{#3}} % \pd{}{}{} - partial derivative, one line\)
 \( \newcommand{\Pd}[3]{\left( \dfrac {\partial #1} {\partial #2}\right)_{#3}} % Pd{}{}{} - Partial derivative, built-up\)
 \( \newcommand{\bpd}[3]{[ \partial #1 / \partial #2 ]_{#3}}\)
 \( \newcommand{\bPd}[3]{\left[ \dfrac {\partial #1} {\partial #2}\right]_{#3}}\)
 \( \newcommand{\dotprod}{\small\bullet}\)
 \( \newcommand{\fug}{f} % fugacity\)
 \( \newcommand{\g}{\gamma} % solute activity coefficient, or gamma in general\)
 \( \newcommand{\G}{\varGamma} % activity coefficient of a reference state (pressure factor)\)
 \( \newcommand{\ecp}{\widetilde{\mu}} % electrochemical or total potential\)
 \( \newcommand{\Eeq}{E\subs{cell, eq}} % equilibrium cell potential\)
 \( \newcommand{\Ej}{E\subs{j}} % liquid junction potential\)
 \( \newcommand{\mue}{\mu\subs{e}} % electron chemical potential\)
\( \newcommand{\defn}{\,\stackrel{\mathrm{def}}{=}\,} % "equal by definition" symbol\)

 \( \newcommand{\D}{\displaystyle} % for a line in built-up\)
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 \( \newcommand{\nextcond}[1]{\\[-5pt]{}\tag*{#1}}\)
 \( \newcommand{\R}{8.3145\units{J$\,$K$\per\,$mol$\per$}}     % gas constant value\)
 \( \newcommand{\Rsix}{8.31447\units{J$\,$K$\per\,$mol$\per$}} % gas constant value - 6 sig figs\)

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