Latest revision as of 12:35, 8 October 2021

Ideal Gas Equation of State

Ideal Gas

Much of the following overview of ideal gas relations is drawn from Chapter II of Chandrasekhar's classic text on Stellar Structure [C67], 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 key equations appendix of this H_Book.

Fundamental Properties of an Ideal Gas

Property #1

An ideal gas containing $n_{g}$ free particles per unit volume will exert on its surroundings an isotropic pressure (i.e., a force per unit area) $P$ given by the following

Standard Form
of the Ideal Gas Equation of State,

$P = n_{g} k T$

[C67], Chapter VII.3, Eq. (18)
[Clayton68], Eq. (2-7)
[H87], §1.1, p. 5

if the gas is in thermal equilibrium at a temperature $T$ .

Property #2

The internal energy per unit mass $ϵ$ of an ideal gas is a function only of the gas temperature $T$ , that is,

$ϵ = ϵ (T) .$

[C67], Chapter II, Eq. (1)

Specific Heats

Drawing from Chapter II, §1 of [C67]: "Let $α$ be a function of the physical variables. Then the specific heat, $c_{α}$ , at constant $α$ is defined by the expression,"

$c_{α}$

$\equiv$

$(\frac{d Q}{d T})_{α = c o n s t a n t}$

The specific heat at constant pressure $c_{P}$ and the specific heat at constant (specific) volume $c_{V}$ prove to be particularly interesting parameters because they identify experimentally measurable properties of a gas.

From the Fundamental Law of Thermodynamics, namely,

$d Q$

$=$

$d ϵ + P d V,$

it is clear that when the state of a gas undergoes a change at constant (specific) volume $(d V = 0)$ ,

$(\frac{d Q}{d T})_{V = c o n s t a n t}$	$=$	$\frac{d ϵ}{d T}$
$\Rightarrow c_{V}$	$=$	$\frac{d ϵ}{d T} .$

Assuming $c_{V}$ is independent of $T$ — a consequence of the kinetic theory of gasses; see, for example, Chapter X of [C67] — and knowing that the specific internal energy is only a function of the gas temperature — see Property #2 above — we deduce that,

$ϵ$

$=$

$c_{V} T .$

[C67], Chapter II, Eq. (10)
[LL75], Chapter IX, §80, Eq. (80.10)
[H87], §1.2, p. 9
[HK94], §3.7.1, immediately following Eq. (3.80)

Also, from Form A of the Ideal Gas Equation of State (see below) and the recognition that $ρ = 1 / V$ , we can write,

$P_{g a s} V$	$=$	$(\frac{ℜ}{\bar{μ}}) T$
$\Rightarrow P d V + V d P$	$=$	$(\frac{ℜ}{\bar{μ}}) d T .$

As a result, the Fundamental Law of Thermodynamics can be rewritten as,

$d Q$

$=$

$c_{V} d T + (\frac{ℜ}{\bar{μ}}) d T - V d P .$

This means that the specific heat at constant pressure is given by the relation,

$c_{P} \equiv (\frac{d Q}{d T})_{P = c o n s t a n t}$

$=$

$c_{V} + \frac{ℜ}{\bar{μ}} .$

That is,

$c_{P} - c_{V}$

$=$

$\frac{ℜ}{\bar{μ}} .$

[C67], Chapter II, §1, Eq. (9)
[Clayton68], Eq. (2-108)
[LL75], Chapter IX, §80, immediately following Eq. (80.11)
[H87], §1.2, p. 9
[KW94], §4.1, immediately following Eq. (4.15)

Consequential Ideal Gas Relations

Throughout most of this H_Book, we will define the relative degree of compression of a gas in terms of its mass density $ρ$ rather than in terms of its number density $n_{g}$ . Following [ Clayton68 ] — see his p. 82 discussion of The Perfect Monatomic Nondegenerate Gas — we will "let the mean molecular weight of the perfect gas be designated by $\bar{μ}$ . Then the density is

$ρ = n_{g} \bar{μ} m_{u},$

where $m_{u}$ is the mass of 1 amu" (atomic mass unit). "The number of particles per unit volume can then be expressed in terms of the density and the mean molecular weight as

$n_{g} = \frac{ρ}{\bar{μ} m_{u}} = \frac{ρ N_{A}}{\bar{μ}},$

where $N_{A}$ = 1/ $m_{u}$ is Avogadro's number …" Substitution into the above-defined Standard Form of the Ideal Gas Equation of State gives, what we will refer to as,

Form A
of the Ideal Gas Equation of State,

$P_{g a s} = \frac{ℜ}{\bar{μ}} ρ T$

[LL75], Chapter IX, §80, Eq. (80.8)
[KW94], §2.2, Eq. (2.7) and §13, Eq. (13.1)

where $ℜ$ ≡ $k$ $N_{A}$ is generally referred to in the astrophysics literature as the gas constant. The definition of the gas constant can be found in the 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 §VII.3 (p. 254) of [C67] or §13.1 (p. 102) of [KW94] for particularly clear explanations of how to calculate $\bar{μ}$ .

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,

$\frac{ℜ}{\bar{μ}} ρ T$

$=$

$(c_{P} - c_{V}) ρ (\frac{ϵ}{c_{V}}) = (γ_{g} - 1) ρ ϵ,$

where we have — as have many before us — introduced a key physical parameter,

$γ_{g}$

$\equiv$

$\frac{c_{P}}{c_{V}},$

[C67], Chapter II, immediately following Eq. (9)
[LL75], Chapter IX, §80, immediately following Eq. (80.9)
[T78], §3.4, immediately following Eq. (72)
[HK94], §3.7.1, Eq. (3.86)

to quantify the ratio of specific heats. This leads to what we will refer to as,

Form B
of the Ideal Gas Equation of State

$P = (γ_{g} - 1) ϵ ρ$

[C67], Chapter II, Eq. (5)
[HK94], §1.3.1, Eq. (1.22)
[BLRY07], §6.1.1, Eq. (6.4)

Related Wikipedia Discussions

@@ Line 27: / Line 27: @@
 [<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>], Chapter VII.3, Eq. (18)<br />
-[http://adsabs.harvard.edu/abs/1968psen.book.....C D. D. Clayton (1968)], Eq. (2-7)<br />
+[<b>[[Appendix/References#Clayton68 |<font color="red">Clayton68</font>]]</b>], Eq. (2-7)<br />
 [<b>[[Appendix/References#H87|<font color="red">H87</font>]]</b>], &sect;1.1, p. 5
 </div>
@@ Line 208: / Line 208: @@
 [<b>[[Appendix/References#C67|<font color="red">C67</font>]]</b>], Chapter II, &sect;1, Eq. (9)<br />
-[http://adsabs.harvard.edu/abs/1968psen.book.....C D. D. Clayton (1968)], Eq. (2-108)<br />
+[<b>[[Appendix/References#Clayton68 |<font color="red">Clayton68</font>]]</b>], Eq. (2-108)<br />
 [<b>[[Appendix/References#LL75|<font color="red">LL75</font>]]</b>], Chapter IX, &sect;80, immediately following Eq. (80.11)<br />
 [<b>[[Appendix/References#H87|<font color="red">H87</font>]]</b>], &sect;1.2, p. 9<br>
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 ==Consequential Ideal Gas Relations==
-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 [http://adsabs.harvard.edu/abs/1968psen.book.....C D. D. Clayton (1968)] &#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>
+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>
 <div align="center">

SR/IdealGas: Difference between revisions

Latest revision as of 12:35, 8 October 2021

Contents

Ideal Gas Equation of State

Fundamental Properties of an Ideal Gas

Property #1

Property #2

Specific Heats

Consequential Ideal Gas Relations

Related Wikipedia Discussions

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SR/IdealGas: Difference between revisions

Latest revision as of 12:35, 8 October 2021

Ideal Gas Equation of State

Fundamental Properties of an Ideal Gas

Property #1

Property #2

Specific Heats

Consequential Ideal Gas Relations

Related Wikipedia Discussions

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