Q. 1.46

Question

Measured heat capacities of solids and liquids are almost always at constant pressure, not constant volume. To see why, estimate the pressure needed to keep $V$ fixed as $T$ increases, as follows.

(a) First imagine slightly increasing the temperature of a material at constant pressure. Write the change in volume, $d V_{1}$ , in terms of $d T$ and the thermal expansion coefficient $β$ introduced in Problem 1.7.

(b) Now imagine slightly compressing the material, holding its temperature fixed. Write the change in volume for this process, $d V_{2}$ , in terms of $d P$ and the isothermal compressibility $κ_{T}$ , defined as

$κ_{T} \equiv - \frac{1}{V} {(\frac{\partial V}{\partial P})}_{T}$

(c) Finally, imagine that you compress the material just enough in part (b) to offset the expansion in part (a). Then the ratio of $d P to d T$ is equal to $(\partial P / \partial T)_{V}$ , since there is no net change in volume. Express this partial derivative in terms of $β and κ_{T}$ . Then express it more abstractly in terms of the partial derivatives used to define $β and κ_{T}$ . For the second expression you should obtain

${(\frac{\partial P}{\partial T})}_{V} = - \frac{(\partial V / \partial T)_{P}}{(\partial V / \partial P)_{T}}$

This result is actually a purely mathematical relation, true for any three quantities that are related in such a way that any two determine the third.

(d) Compute $β, κ_{T}, and (\partial P / \partial T)_{V}$ for an ideal gas, and check that the three expressions satisfy the identity you found in part (c).

(e) For water at $25^{\circ} C, β = 2.57 \times 10^{- 4} K^{- 1} and κ_{T} = 4.52 \times 10^{- 10} {Pa}^{- 1}$ . Suppose you increase the temperature of some water from $20^{\circ} C to 30^{\circ} C$ . How much pressure must you apply to prevent it from expanding? Repeat the calculation for mercury, for which $(at 25^{\circ} C) β = 1.81 \times 10^{- 4} K^{- 1}$ and $κ_{T} = 4.04 \times 10^{- 11} {Pa}^{- 1}$

Given the choice, would you rather measure the heat capacities of these substances at constant $v$ or at constant $p$ ?

Step-by-Step Solution

Verified

Answer

(A) The change in volume in $d V_{1}$ and thermal coefficient is $d V_{1} = β V d T$

(B) The change in volume of $d V_{2}$ is $d V_{2} = - κ_{T} V d P$

(C) The second expression is ${(\frac{\partial P}{\partial T})}_{V} = - \frac{(\partial V / \partial T)_{P}}{(\partial V / \partial P)_{T}}$

(D) An ideal gas of three expression is $β = \frac{1}{T}, κ_{T} = \frac{1}{P} . \frac{P}{T} = \frac{β}{κ_{T}}$

(E) The heat capacities of substances constant is $Δ P_{water} = 5.686 \times 10^{6} Pa, Δ P_{mercury} = 4.48 \times 10^{7} Pa$

1Step :1 The thermal expansion coefficient (part a)

Substances' heat capacity can be determined at constant volume or constant pressure. It's relatively simple to assess a gas's heat capacity by enclosing it in a sealed container and keeping it at a constant volume. However, measuring heat capacity at constant pressure is much easier for solids and liquids. We can calculate how much pressure must be increased to prevent a solid or liquid from expanding when heated.

(a) The thermal expansion coefficient is:

$β = \frac{Δ V / V}{Δ T}$

Imagine that the substrate atmospheric temperature slightly at constant pressure, and the thermal expansion coefficient, which is a measure of the relative volume change with temperature at constant pressure, is:

$β = \frac{Δ V / V}{Δ T} = \frac{1}{V} {(\frac{\partial V}{\partial T})}_{p} \to {(\frac{\partial V}{\partial T})}_{p} = β V$

However, because $V$ is a function of $T and P, V (T, P)$ , the volume change due to the differential:

$d V = {(\frac{\partial V}{\partial P})}_{T} d P + {(\frac{\partial V}{\partial T})}_{P} d T$

Equation (2) becomes: $d p = 0$ at constant pressure.

$d V = {(\frac{\partial V}{\partial T})}_{P} d T$

Substitute $(2)$ for $(1)$ to get the following volume change:

$d V_{1} = β V d T$

2Step :2 Constant temperature (part b)

(b) Assume we compress a solid (or a liquid) slightly at constant temperature $d T = 0$ , resulting in equation $(2)$ :

$d V = {(\frac{\partial V}{\partial P})}_{T} d P$

Given that the isothermal compressibility is the reciprocal of the bulk modulus:

$κ_{T} = - \frac{1}{V} {(\frac{\partial V}{\partial P})}_{T} \to {(\frac{\partial V}{\partial P})}_{T} = - κ_{T} V$

Substituting equation $(5)$ into equation $(4)$ , the volume change is:

$d V_{2} = - κ_{T} V d P$

3Step :3 Change in volume after two action (part c)

$d V_{1} + d V_{2} = 0 \to d V_{1} = - d V_{2}$

Substitute

$β V d T = κ_{T} V d P$

$\to {(\frac{\partial P}{\partial T})}_{V} = \frac{β}{κ_{T}}$

From $(1) a n d (5)$

${(\frac{\partial P}{\partial T})}_{V} = \frac{β}{κ y} = \frac{\frac{1}{V} {(\frac{\partial V}{\partial T})}_{Γ}}{\frac{1}{V} {(\frac{\partial V}{\partial P})}_{T}}$

$\to {(\frac{\partial P}{\partial T})}_{V} = - \frac{{(\frac{\partial P}{\partial T})}_{T}}{{(\frac{\partial V}{\partial P})}_{T}}$

$\to {(\frac{\partial P}{\partial T})}_{V} = - \frac{(\partial V / \partial T)_{P}}{(\partial V / \partial P)_{T}}$

4Step :4 Ideal gas law (part d)

(d) From the ideal gas law, $P V = N k T$ , and using equation $(5)$ and $(1)$ we have:

$β = \frac{1}{V} {(\frac{\partial V}{\partial T})}_{p} = \frac{1}{V} {(\frac{\partial (\frac{N k T}{P})}{\partial T})}_{p}$

$\to β = \frac{N k}{P V} = \frac{N k}{N k T} = \frac{1}{T}$

$κ_{T} = - \frac{1}{V} {(\frac{\partial V}{\partial P})}_{T} = - \frac{1}{V} {(\frac{\partial (\frac{N k T}{P})}{\partial P})}_{T} = \frac{N k T}{V P^{2}}$

$\to κ_{T} = \frac{N k T}{V P^{2}} = \frac{N k T}{(V P) P} = \frac{N k T}{(N k T) P} = \frac{1}{P}$

Divide

$\to \frac{P}{T} = \frac{β}{κ_{T}}$

Now from equation

${(\frac{\partial P}{\partial T})}_{V} = \frac{β}{κ_{T}}$

$\to {(\frac{\partial (\frac{N k T}{V})}{\partial T})}_{V} = \frac{β}{κ_{T}}$

$\to \frac{N k}{V} = \frac{β}{κ_{T}}$

$\to \frac{P}{T} = \frac{β}{κ_{T}}$

We can conclude that the results from $(d)$ , equation , and $(c)$ equation , are identical.

5Step :5 For water (part e)

(e) For water, the given values are:

$\begin{matrix} β = 2.57 \times 10^{- 4} K^{- 1} \\ κ = 4.52 \times 10^{- 10} {Pa}^{- 1} \end{matrix}$

So the pressure increase

$\frac{P}{T} = \frac{β}{κ_{T}} \to P = \frac{β}{κ_{T}} T \to Δ P = \frac{β}{κ_{T}} Δ T$

But the temperature difference is

$Δ T = T_{f} - T_{i} = 30 - 20 = 10^{\circ} K$

So the pressure difference is

$Δ P = \frac{β}{κ_{T}} Δ T = \frac{2.57 \times 10^{- 4}}{4.52 \times 10^{- 10}} \times 10 = 5.686 \times 10^{6} Pa$

$\to Δ P = 5.686 \times 10^{6} Pa$

For mercury the temperature range is

$\begin{matrix} β = 1.81 \times 10^{- 4} K^{- 1} \\ κ = 4.04 \times 10^{- 11} {Pa}^{- 1} \end{matrix}$

So the pressure increase must be

$\begin{aligned} Δ P = \frac{β}{κ_{T}} Δ T = \frac{1.81 \times 10^{- 4}}{4.04 \times 10^{- 11}} \times 10 \\ \to Δ P = 4.48 \times 10^{7} Pa \end{aligned}$

Q. 1.41.

Q.1.47

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