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Chapter 2: Systems and Their Properties

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 \( \newcommand{\Cpm}{C_{p,\text{m}}} % molar heat capacity at const.p\)
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 \( \newcommand{\kHi}{k_{\text{H},i}}      % Henry's law constant, x basis, i\)
 \( \newcommand{\kHB}{k_{\text{H,B}}}      % Henry's law constant, x basis, B\)
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 \(\newcommand{\dBar}{\mathop{}\!\mathrm{d}\hspace-.3em\raise1.05ex{\Rule{.8ex}{.125ex}{0ex}}} % inexact differential \)
 \( \newcommand{\dq}{\dBar q} % heat differential\)
 \( \newcommand{\dw}{\dBar w} % work differential\)
 \( \newcommand{\dQ}{\dBar Q} % infinitesimal charge\)
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 \( \newcommand{\G}{\varGamma} % activity coefficient of a reference state (pressure factor)\)
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This chapter begins by explaining some basic terminology of thermodynamics.  It discusses macroscopic properties of matter in general and properties distinguishing different physical states of matter in particular.  Virial equations of state of a pure gas are introduced.  The chapter goes on to discuss some basic macroscopic properties and their measurement.  Finally, several important concepts needed in later chapters are described: thermodynamic states and state functions, independent and dependent variables, processes, and internal energy.

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