https://selfgravitatingfluids.education/JETohline/index.php?action=history&feed=atom&title=SR%2FIdealGasSR/IdealGas - Revision history2026-04-26T13:48:10ZRevision history for this page on the wikiMediaWiki 1.43.1https://selfgravitatingfluids.education/JETohline/index.php?title=SR/IdealGas&diff=15&oldid=prevJoel2: Created page with "__FORCETOC__ <!-- will force the creation of a Table of Contents --> <!-- __NOTOC__ will force TOC off --> =Ideal Gas Equation of State= {| class="PGEclass" style="float:left; margin-right: 20px; border-style: solid; border-width: 3px border-color: black" |- ! style="height: 125px; width: 125px; background-color:white;" | <font size="-1"><b>Ideal Gas</b></font> |} Much of the following overview of ideal gas relations is drawn from Chapter I..."2023-12-11T20:03:41Z<p>Created page with "__FORCETOC__ <!-- will force the creation of a Table of Contents --> <!-- __NOTOC__ will force TOC off --> =Ideal Gas Equation of State= {| class="PGEclass" style="float:left; margin-right: 20px; border-style: solid; border-width: 3px border-color: black" |- ! style="height: 125px; width: 125px; background-color:white;" | <font size="-1"><a href="/JETohline/index.php/H_BookTiledMenu#Context" title="H BookTiledMenu"><b>Ideal Gas</b></a></font> |} Much of the following overview of ideal gas relations is drawn from Chapter I..."</p>
<p><b>New page</b></p><div>__FORCETOC__ <!-- will force the creation of a Table of Contents --><br />
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=Ideal Gas Equation of State=<br />
<br />
{| class="PGEclass" style="float:left; margin-right: 20px; border-style: solid; border-width: 3px border-color: black"<br />
|- <br />
! style="height: 125px; width: 125px; background-color:white;" |<br />
<font size="-1">[[H_BookTiledMenu#Context|<b>Ideal Gas</b>]]</font><br />
|}<br />
<br />
Much of the following overview of ideal gas relations is drawn from Chapter II of Chandrasekhar's classic text on ''Stellar Structure'' [[Appendix/References#C67|[<b><font color="red">C67</font></b>]]], which was originally published in 1939. A guide to parallel ''print media'' discussions of this topic is provided alongside the ideal gas equation of state in the [[Appendix/EquationTemplates#Equations_of_State|key equations appendix]] of this H_Book.<br />
<br />
&nbsp;<br /><br />
&nbsp;<br /><br />
&nbsp;<br /><br />
==Fundamental Properties of an Ideal Gas==<br />
<br />
===Property #1=== <br />
<br />
An ideal gas containing {{ Template:Math/VAR_NumberDensity01 }} free particles per unit volume will exert on its surroundings an isotropic pressure (''i.e.'', a force per unit area) {{ Template:Math/VAR_Pressure01 }} given by the following<br />
<br />
<div align="center"><br />
<span id="IdealGas:StandardForm"><font color="#770000">'''Standard Form'''</font></span><br /><br />
of the Ideal Gas Equation of State,<br />
<br />
{{ Template:Math/EQ_EOSideal00 }}<br />
<br />
[<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>], Chapter VII.3, Eq. (18)<br /><br />
[<b>[[Appendix/References#Clayton68 |<font color="red">Clayton68</font>]]</b>], Eq. (2-7)<br /><br />
[<b>[[Appendix/References#H87|<font color="red">H87</font>]]</b>], &sect;1.1, p. 5<br />
</div><br />
<br />
if the gas is in thermal equilibrium at a temperature {{ Template:Math/VAR_Temperature01 }}.<br />
<br />
===Property #2=== <br />
<br />
The internal energy per unit mass {{ Template:Math/VAR_SpecificInternalEnergy01 }} of an ideal gas is a function ''only'' of the gas temperature {{ Template:Math/VAR_Temperature01 }}, that is,<br />
<br />
<div align="center"><br />
<math>~\epsilon = \epsilon(T) \, .</math><br />
<br />
[<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>], Chapter II, Eq. (1)<br />
</div><br />
<br />
==Specific Heats==<br />
<br />
Drawing from Chapter II, &sect;1 of [<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>]:&nbsp; "<font color="#007700">Let <math>\alpha</math> be a function of the physical variables. Then the specific heat, <math>c_\alpha</math>, at constant <math>\alpha</math> is defined by the expression,</font>"<br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>c_\alpha</math><br />
</td><br />
<td align="center"><br />
<math>\equiv</math><br />
</td><br />
<td align="left"><br />
<math>\biggl( \frac{dQ}{dT} \biggr)_{\alpha ~=~ \mathrm{constant}}</math><br />
</td><br />
</tr><br />
</table><br />
The specific heat at constant pressure <math>c_P</math> and the specific heat at constant (specific) volume <math>c_V</math> prove to be particularly interesting parameters because they identify experimentally measurable properties of a gas. <br />
<br />
From the [[PGE/FirstLawOfThermodynamics#FundamentalLaw|Fundamental Law of Thermodynamics]], namely,<br />
<br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>dQ</math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math><br />
d\epsilon + PdV \, ,<br />
</math><br />
</td><br />
</tr><br />
</table><br />
it is clear that when the state of a gas undergoes a change at constant (specific) volume <math>(dV = 0)</math>,<br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>\biggl( \frac{dQ}{dT} \biggr)_{V ~=~ \mathrm{constant}}</math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math>\frac{d\epsilon}{dT}</math><br />
</td><br />
</tr><br />
<br />
<tr><br />
<td align="right"><br />
<math>\Rightarrow ~~~ c_V</math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math>\frac{d\epsilon}{dT} \, .</math><br />
</td><br />
</tr><br />
</table><br />
Assuming <math>c_V</math> is independent of {{ Template:Math/VAR_Temperature01 }} &#8212; a consequence of the kinetic theory of gasses; see, for example, Chapter X of [<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>] &#8212; and knowing that the specific internal energy is only a function of the gas temperature &#8212; see ''[[#Property_.232|Property #2]]'' above &#8212; we deduce that,<br />
<div align="center"><br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>\epsilon</math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math>c_V T \, .</math><br />
</td><br />
</tr><br />
</table><br />
<br />
[<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>], Chapter II, Eq. (10)<br /><br />
[<b>[[Appendix/References#LL75|<font color="red">LL75</font>]]</b>], Chapter IX, &sect;80, Eq. (80.10)<br /><br />
[<b>[[Appendix/References#H87|<font color="red">H87</font>]]</b>], &sect;1.2, p. 9<br /><br />
[<b>[[Appendix/References#HK94|<font color="red">HK94</font>]]</b>], &sect;3.7.1, immediately following Eq. (3.80)<br />
</div><br />
<br />
Also, from ''Form A of the Ideal Gas Equation of State'' (see below) and the recognition that <math>\rho = 1/V</math>, we can write,<br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>P_\mathrm{gas}V</math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math>\biggl(\frac{\Re}{\bar\mu} \biggr) T</math><br />
</td><br />
</tr><br />
<br />
<tr><br />
<td align="right"><br />
<math>\Rightarrow ~~~ PdV + VdP</math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math>\biggl(\frac{\Re}{\bar\mu} \biggr) dT \, .</math><br />
</td><br />
</tr><br />
</table><br />
As a result, the [[PGE/FirstLawOfThermodynamics#FundamentalLaw|Fundamental Law of Thermodynamics]] can be rewritten as,<br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>dQ</math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math>c_\mathrm{V} dT + \biggl(\frac{\Re}{\bar\mu} \biggr) dT - VdP \, .</math><br />
</td><br />
</tr><br />
</table><br />
This means that the specific heat at constant pressure is given by the relation,<br />
<div align="center"><br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>c_P \equiv \biggl( \frac{dQ}{dT} \biggr)_{P ~=~ \mathrm{constant}}</math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math>c_V + \frac{\Re}{\bar\mu} \, .</math><br />
</td><br />
</tr><br />
</table><br />
</div><br />
<br />
That is,<br />
<div align="center"><br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>c_P - c_V </math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math>\frac{\Re}{\bar\mu} \, .</math><br />
</td><br />
</tr><br />
</table><br />
<br />
[<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>], Chapter II, &sect;1, Eq. (9)<br /><br />
[<b>[[Appendix/References#Clayton68 |<font color="red">Clayton68</font>]]</b>], Eq. (2-108)<br /><br />
[<b>[[Appendix/References#LL75|<font color="red">LL75</font>]]</b>], Chapter IX, &sect;80, immediately following Eq. (80.11)<br /><br />
[<b>[[Appendix/References#H87|<font color="red">H87</font>]]</b>], &sect;1.2, p. 9<br><br />
[<b>[[Appendix/References#KW94|<font color="red">KW94</font>]]</b>], &sect;4.1, immediately following Eq. (4.15) <br />
</div><br />
<br />
==Consequential Ideal Gas Relations==<br />
<br />
Throughout most of this H_Book, we will define the relative degree of compression of a gas in terms of its mass density {{ Template:Math/VAR_Density01 }} rather than in terms of its number density {{ Template:Math/VAR_NumberDensity01 }}. Following [<b>[[Appendix/References#Clayton68|<font color="red"> Clayton68 </font>]]</b>] &#8212; see his p. 82 discussion of ''The Perfect Monatomic Nondegenerate Gas'' &#8212; we will "<font color="#007700">let the mean molecular weight of the perfect gas be designated by {{ Template:Math/MP_MeanMolecularWeight }}. Then the density is</font><br />
<br />
<div align="center"><br />
<math>\rho = n_g \bar\mu m_u \, ,</math><br />
</div><br />
<br />
<font color="#007700">where {{ Template:Math/C_AtomicMassUnit }} is the mass of 1 amu</font>" ([https://en.wikipedia.org/wiki/Unified_atomic_mass_unit atomic mass unit]). "<font color="#007700">The number of particles per unit volume can then be expressed in terms of the density and the mean molecular weight as</font><br />
<br />
<div align="center"><br />
<math>n_g = \frac{\rho}{\bar\mu m_u} = \frac{\rho N_A}{\bar\mu} \, ,</math><br />
</div><br />
<br />
<font color="#007700">where {{ Template:Math/C_AvogadroConstant }} = 1/{{ Template:Math/C_AtomicMassUnit }} is Avogadro's number &hellip;</font>" Substitution into the [[#Fundamental_Properties_of_an_Ideal_Gas|above-defined ''Standard Form of the Ideal Gas Equation of State'']] gives, what we will refer to as,<br />
<br />
<div align="center"><br />
<span id="IdealGas:FormA"><font color="#770000">'''Form A'''</font></span><br /><br />
of the Ideal Gas Equation of State,<br />
<br />
{{ Template:Math/EQ_EOSideal0A }}<br />
<br />
[<b>[[Appendix/References#LL75|<font color="red">LL75</font>]]</b>], Chapter IX, &sect;80, Eq. (80.8)<br /><br />
[<b>[[Appendix/References#KW94|<font color="red">KW94</font>]]</b>], &sect;2.2, Eq. (2.7) and &sect;13, Eq. (13.1)<br />
</div><br />
<br />
where {{ Template:Math/C_GasConstant}} &equiv; {{ Template:Math/C_BoltzmannConstant }}{{ Template:Math/C_AvogadroConstant }} is generally referred to in the astrophysics literature as the gas constant. The definition of the gas constant can be found in the [[Appendix/VariablesTemplates|Variables Appendix]] of this H_Book; its numerical value can be obtained by simply scrolling the computer mouse over its symbol in the text of this paragraph. See &sect;VII.3 (p. 254) of [[Appendix/References#C67|[<b><font color="red">C67</font></b>]]] or &sect;13.1 (p. 102) of [[Appendix/References#KW94|[<b><font color="red">KW94</font></b>]]] for particularly clear explanations of how to calculate {{ Template:Math/MP_MeanMolecularWeight }}.<br />
<br />
<!--<br />
<div align="center"><br />
<table border=1 cellpadding=8 width="80%"><br />
<tr><td><br />
<font color="red"><br />
Exercise:<br />
</font><br />
If {{User:Tohline/Math/C_GasConstant}} is defined as the product of the Boltzmann constant {{User:Tohline/Math/C_BoltzmannConstant}} and the Avogadro constant {{User:Tohline/Math/C_AvogadroConstant}}, as stated in the [[User:Tohline/Appendix/Variables_templates|Variables Appendix]] of this H_Book, show that "Form A" and the "Standard Form" of the ideal gas equation of state provide equivalent expressions only if <math>~(\bar\mu)^{-1}</math> gives the number of free particles per atomic mass unit, {{User:Tohline/Math/C_AtomicMassUnit}}. <br />
</td></tr><br />
</table><br />
</div><br />
--><br />
Employing a couple of the expressions from the above discussion of specific heats, the right-hand side of ''Form A of the Ideal Gas Equation of State'' can be rewritten as,<br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>\frac{\Re}{\bar\mu} \rho T</math><br />
</td><br />
<td align="center"><br />
<math>=</math><br />
</td><br />
<td align="left"><br />
<math><br />
(c_P - c_V)\rho \biggl(\frac{\epsilon}{c_V}\biggr)<br />
=<br />
(\gamma_g - 1)\rho\epsilon \, ,<br />
</math><br />
</td><br />
</tr><br />
</table><br />
<span id="gamma_g">where we have &#8212; as have many before us &#8212; introduced a key physical parameter,</span><br />
<div align="center"><br />
<table border="0" cellpadding="5" align="center"><br />
<br />
<tr><br />
<td align="right"><br />
<math>\gamma_g</math><br />
</td><br />
<td align="center"><br />
<math>\equiv</math><br />
</td><br />
<td align="left"><br />
<math>\frac{c_P}{c_V} \, ,</math><br />
</td><br />
</tr><br />
</table><br />
<br />
[<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>], Chapter II, immediately following Eq. (9)<br /><br />
[<b>[[Appendix/References#LL75|<font color="red">LL75</font>]]</b>], Chapter IX, &sect;80, immediately following Eq. (80.9)<br /><br />
[<b>[[Appendix/References#T78|<font color="red">T78</font>]]</b>], &sect;3.4, immediately following Eq. (72)<br /><br />
[<b>[[Appendix/References#HK94|<font color="red">HK94</font>]]</b>], &sect;3.7.1, Eq. (3.86)<br />
</div><br />
<br />
to quantify the ratio of specific heats. This leads to what we will refer to as,<br />
<div align="center"><br />
<span id="IdealGasFormB"><font color="#770000">'''Form B'''</font></span><br /><br />
of the Ideal Gas Equation of State<br />
<br />
{{ Template:Math/EQ_EOSideal02 }}<br />
<br />
[<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>], Chapter II, Eq. (5)<br /><br />
[<b>[[Appendix/References#HK94|<font color="red">HK94</font>]]</b>], &sect;1.3.1, Eq. (1.22)<br /><br />
[<b>[[Appendix/References#BLRY07|<font color="red">BLRY07</font>]]</b>], &sect;6.1.1, Eq. (6.4)<br />
</div><br />
<br />
=Related Wikipedia Discussions=<br />
* [http://en.wikipedia.org/wiki/Equation_of_state#Classical_ideal_gas_law Equation of State: Classical ideal gas law]<br />
* [http://en.wikipedia.org/wiki/Ideal_gas_law Ideal Gas Law]<br />
* [http://en.wikipedia.org/wiki/Ideal_gas Ideal Gas]<br />
<br />
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{{ SGFfooter }}</div>Joel2