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An Introduction to Thermal Physics

Daniel V. Schroeder

Physics

1st Edition · 356 pages

ISBN: 9780201380279

Chapter 1: Q. 1.58 (page 40)

According to a standard reference table, the R value of a 3.5 inch-thick vertical air space (within a wall) is 1.0 R in English units), while the R value of a 3.5-inch thickness of fiberglass batting is 10.9. Calculate the R value of a 3.5-inch thickness of still air, then discuss whether these two numbers are reasonable. (Hint: These reference values include the effects of convection.)

Short Answer

Expert verified

The value of 3.5 inch thickness of still air is R_air= 0.176 m². ^oK.s.J^-1

Step by step solution

01

To Calculate R

$R$ value is,

$R = \frac{Δ k}{k_{t}}$

For

localid="1651328451771" $air k_{t} = 0.026 {Wm}^{- 1} k^{- 1}$

So,

$3.5 i n c h = 3.5 \times 25.6 m m$

$= 89.6 \times 10^{- 3} m$

$R_{air} = \frac{89.6 \times 10^{- 3} m}{0.026 {Wm}^{- 1} K^{- 1}}$

$= 3.45 ω^{- 1} m^{2} k$

02

After conversion.

Then,

$R_{air} = \frac{3.45}{0.58}$ role="math" localid="1651327954414" $o f f t^{2} h r / b t u$

$R_{a i r} = 5.95$ role="math" $o f f t^{2} h r / b t u$

As a result, the value does not match the reference value $(f = 1)$ .

Because of the convection process, reference values incorporate the impacts of convection.

The air's thermal conductivity rises.

As a result, the value of $R$ decreases.

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Most popular questions from this chapter

Heat capacities are normally positive, but there is an important class of exceptions: systems of particles held together by gravity, such as stars and star clusters.
$(a)$ Consider a system of just two particles, with identical masses, orbiting in circles about their center of mass. Show that the gravitational potential energy of this system is- $2$ times the total kinetic energy.
$(b)$ The conclusion of part $(a)$ turns out to be true, at least on average, for any system of particles held together by mutual gravitational attraction:

${\bar{U}}_{potential} = - 2 {\bar{U}}_{kinetic}$

Here each $U$ refers to the total energy (of that type) for the entire system, averaged over some sufficiently long time period. This result is known as the virial theorem. (For a proof, see Carroll and Ostlie ( $1996$ ), Section $2.4$ .) Suppose, then, that you add some energy to such a system and then wait for the system to equilibrate. Does the average total kinetic energy increase or decrease? Explain.

$(c)$ A star can be modeled as a gas of particles that interact with each other only gravitationally. According to the equipartition theorem, the average kinetic energy of the particles in such a star should be $\frac{3}{2} K T$ , where $T$ is the average temperature. Express the total energy of a star in terms of its average temperature, and calculate the heat capacity. Note the sign.
$(d)$ Use dimensional analysis to argue that a star of mass $M$ and radius $R$ should have a total potential energy of $- G M^{2} / R$ , times some constant of order $1 .$
$(e)$ Estimate the average temperature of the sun, whose mass is $2 \times 10^{30} k g$ and whose radius is $7 \times 10^{8} m$ . Assume, for simplicity, that the sun is made entirely of protons and electrons.

A battery is connected in series to a resistor, which is immersed in water (to prepare a nice hot cup of tea). Would you classify the flow of energy from the battery to the resistor as "heat" or "work"? What about the flow of energy from the resistor to the water?

Make a rough estimate of how far food coloring (or sugar) will diffuse through water in one minute.

A frying pan is quickly heated on the stovetop $200^{\circ} C$ It has an iron handle that is $20 c m$ long. Estimate how much time should pass before the end of the handle is too hot to grab with your bare hand. (Hint: The cross-sectional area of the handle doesn't matter. The density of iron is about $7.9 g / {cm}^{3}$ and its specific heat is $0.45 J / g \cdot^{\circ} C$ ).

Consider the combustion of one mole of methane gas:

${CH}_{4} (gas) + 2 O_{2} (gas) ⟶ {CO}_{2} (gas) + 2 H_{2} O (gas)$

The system is at standard temperature $(298 K)$ and pressure $(10^{5} Pa)$ both before and after the reaction.

(a) First imagine the process of converting a mole of methane into its elemental constituents (graphite and hydrogen gas). Use the data at the back of this book to find $Δ H$ for this process.

(b) Now imagine forming a mole of ${CO}_{2}$ and two moles of water vapor from their elemental constituents. Determine $Δ H$ for this process.

(c) What is $Δ H$ for the actual reaction in which methane and oxygen form carbon dioxide and water vapor directly? Explain.

(d) How much heat is given off during this reaction, assuming that no "other" forms of work are done?

(e) What is the change in the system's energy during this reaction? How would your answer differ if the $H_{2} O$ ended up as liquid water instead of vapor?

(f) The sun has a mass of $2 \times 10^{30} kg$ and gives off energy at a rate of $3.9 \times$ $10^{26}$ watts. If the source of the sun's energy were ordinary combustion of a chemical fuel such as methane, about how long could it last?

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