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An Introduction to Thermal Physics

Daniel V. Schroeder

Physics

1st Edition · 356 pages

ISBN: 9780201380279

Chapter 1: 1.19. (page 13)

Suppose you have a gas containing hydrogen molecules and oxygen molecules, in thermal equilibrium. Which molecule are moving faster, on average? By what factor?

Short Answer

Expert verified

In thermal equilibrium, hydrogen molecules moves faster by a factor of 4

Step by step solution

01

Concept of thermal equilibrium which relates with the rms speed of molecules.

Thermal equilibrium refers that both the molecules have same temperature, Hence we can write

$\frac{3}{2} K T = \frac{1}{2} m v^{2} v = \sqrt{\frac{3 K T}{m}}$

02

Relation of speed with molar mass.

From the above equation we can say that $v α \frac{1}{\sqrt{m}}$

Thus the molecule with least mass will have maximum rms speed.

Now O₂ had molecular mass of 32 & H₂ has molecular mass of 2

$\frac{{m_{H}}_{2}}{{m_{O}}_{2}} = 16$

03

Arriving at the result.

Thus we can say that hydrogen with least mass has the maximum rms speed and

$\frac{v_{H_{2}}}{v_{O_{2}}} = \sqrt{\frac{m_{O_{2}}}{m_{H_{2}}} =} \sqrt{\frac{1}{16}} v_{O_{2}} = 4 v_{H_{2}}$

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Most popular questions from this chapter

By applying Newton’s laws to the oscillations of a continuous medium, one can show that the speed of a sound wave is given by

$c_{s} = \sqrt{\frac{B}{ρ}}$ ,

where $ρ$ is the density of the medium (mass per unit volume) and B is the bulk modulus, a measure of the medium’s stiffness? More precisely, if we imagine applying an increase in pressure $Δ P$ to a chunk of the material, and this increase results in a (negative) change in volume $Δ V$ , then B is defined as the change in pressure divided by the magnitude of the fractional change in volume:

$B = \frac{Δ P}{- Δ V / V}$

This definition is still ambiguous, however, because I haven't said whether the compression is to take place isothermally or adiabatically (or in some other way).

Compute the bulk modulus of an ideal gas, in terms of its pressure P, for both isothermal and adiabatic compressions.
Argue that for purposes of computing the speed of a sound wave, the adiabatic B is the one we should use.
Derive an expression for the speed of sound in an ideal gas, in terms of its temperature and average molecular mass. Compare your result to the formula for the RMS speed of the molecules in the gas. Evaluate the speed of sound numerically for air at room temperature.
When Scotland’s Battlefield Band played in Utah, one musician remarked that the high altitude threw their bagpipes out of tune. Would you expect altitude to affect the speed of sound (and hence the frequencies of the standing waves in the pipes)? If so, in which direction? If not, why not?

Look up the enthalpy of formation of atomic hydrogen in the back of this book. This is the enthalpy change when a mole of atomic hydrogen is formed by dissociating $1 / 2$ mole of molecular hydrogen (the more stable state of the element). From this number, determine the energy needed to dissociate a single $H_{2}$ molecule, in electron-volts.

By applying a pressure of $200 a t m$ , you can compress water to $99 %$ of its usual volume. Sketch this process (not necessarily to scale) on a $P V$ diagram, and estimate the work required to compress a liter of water by this amount. Does the result surprise you?

Consider a uniform rod of material whose temperature varies only along its length, in the $x$ direction. By considering the heat flowing from both directions into a small segment of length $Δ x$

derive the heat equation,

$\frac{\partial T}{\partial t} = K \frac{\partial^{2} T}{\partial x^{2}}$

where $K = k_{t} / c ρ_{i}$ , $c$ is the specific heat of the material, and $ρ$ is its density. (Assume that the only motion of energy is heat conduction within the rod; no energy enters or leaves along the sides.) Assuming that $K$ is independent of temperature, show that a solution of the heat equation is

$T (x, t) = T_{0} + \frac{A}{\sqrt{t}} e^{- x^{2} / 4 K t},$

where $T_{0}$ is a constant background temperature and $A$ is any constant. Sketch (or use a computer to plot) this solution as a function of $x$ , for several values of $t$ . Interpret this solution physically, and discuss in some detail how energy spreads through the rod as time passes.

During a hailstorm, hailstones with an average mass of 2g and a speed of 15 m/s strike a window pane at a 45^o angle. The area of the window is 0.5 m² and the hailstones hit it at a rate of 30 per second. What average pressure do they exert on the window? How does this compare to the pressure of the atmosphere?

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