An Introduction to Thermal Physics
1st Edition
ISBN: 9780201380279
Author: Daniel V. Schroeder
Publisher: Addison Wesley
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Textbook Question
Chapter 1.5, Problem 34P
An ideal diatomic gas, in a cylinder with a movable piston, undergoes the rectangular
- For each of the steps A through D, compute the work done on the gas, the heat added to the gas, and the change in the energy content of the gas. Express all answers in terms of
ideal gas law and the equipartition theorem.) - Describe in words what is physically being done during each of the four steps; for example, during step A, heat is added to the gas (from an external flame or something) while the piston is held fixed.
- Compute the net work done on the gas, the net heat added to the gas, and the net change in the energy of the gas during the entire cycle. Are the results as you expected? Explain briefly.
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Problem 4.1. Recall Problem 1.34, which concerned an ideal diatomic gas taken around a rectangular cycle on a PV diagram. Suppose now that this system is used as a heat engine, to convert the heat added into mechanical work. (a) Evaluate the efficiency of this engine for the case V2 = 3V1, P2 = 2P1. (b) Calculate the efficiency of an "ideal" engine operating between the same temperature extremes.
Problem 1.33. An ideal gas is made to undergo the cyclic process shown in
Figure 1.10(a). For each of the steps A, B, and C, determine whether each of
the following is positive, nogative, or zero: (a) the work done on the gas; (b) the
change in the energy content of the gas: (c) the heat added to the gas. Then
determine the sign of each of these three quantities for the whole cycle. What does
this process accomplish?
(a)
A (b)
B
Pa
B
A
A
D
Volume
V1
V Volume
Figure 1.10. PV diagrams for Problems 1.33 and 1.34.
steps; for example, during step A, heat is added to the gas (from an external
flame or something) while the piston is held fixed.
(c) Compute the net work done on the gas, the net heat added to the gas, and
the net change in the energy of the gas during the entire cycle. Are the
results as you expected? Explain briefly.
Show that knowing the initial condition of a compressed system consisting of a gas
you can derive its final temperature.
Pressure
Pressure
rork 28 the ofnly
Problem 1.31. Imagine some helium in a cylinder with an initial volume of 1 liter
and an initial pressure of 1 atm. Somehow the helium is made to expand to a final
volume of 3 liters, in such a way that its pressure rises in direct proportion to its
volume.
(a) Sketch a graph of pressure vs. volume for this process.
(b) Calculate the work done on the gas during this process, assuming that there
are no "other" types of work being done.
(c) Calculate the change in the helium's energy content during this process.
(d) Calculate the amount of heat added to or removed from the helium during
this process.
(e) Describe what you might do to cause the pressure to rise as the helium
еxpands.
Problem 1.33. An ideal gas is made to undergo the cyclic process shown in
Figure 1.10(a). For each of the steps A, B, and C, determine whether each of
the following is positive, nogative, or zero: (a) the work done on the gas; (b) the
change in the energy content of the gas; (c) the heat…
Chapter 1 Solutions
An Introduction to Thermal Physics
Ch. 1.1 - Prob. 1PCh. 1.1 - The Rankine temperature scale (abbreviatedR) uses...Ch. 1.1 - Prob. 3PCh. 1.1 - Does it ever make sense to say that one object is...Ch. 1.1 - Prob. 5PCh. 1.1 - Give an example to illustrate why you cannot...Ch. 1.1 - Prob. 7PCh. 1.1 - For a solid, we also define the linear thermal...Ch. 1.2 - What is the volume of one mole of air, at room...Ch. 1.2 - Energy in Thermal Physics Estimate the number of...
Ch. 1.2 - Rooms A and B are the same size, and are connected...Ch. 1.2 - Calculate the average volume per molecule for an...Ch. 1.2 - A mole is approximately the number of protons in a...Ch. 1.2 - Calculate the mass of a mole of dry air, which is...Ch. 1.2 - Estimate the average temperature of the air inside...Ch. 1.2 - Prob. 16PCh. 1.2 - Prob. 17PCh. 1.2 - Prob. 18PCh. 1.2 - Suppose you have a gas containing hydrogen...Ch. 1.2 - Prob. 20PCh. 1.2 - During a hailstorm, hailstones with an average...Ch. 1.2 - Prob. 22PCh. 1.3 - Calculate the total thermal energy in a liter of...Ch. 1.3 - Calculate the total thermal energy in a gram of...Ch. 1.3 - List all the degrees of freedom, or as many as you...Ch. 1.4 - A battery is connected in series to a resistor,...Ch. 1.4 - Give an example of a process in which no heat is...Ch. 1.4 - Estimate how long it should take to bring a cup of...Ch. 1.4 - A cup containing 200 g of water is sitting on your...Ch. 1.4 - Put a few spoonfuls of water into a bottle with a...Ch. 1.5 - Imagine some helium in cylinder with an initial...Ch. 1.5 - Prob. 32PCh. 1.5 - An ideal gas is made to undergo the cyclic process...Ch. 1.5 - An ideal diatomic gas, in a cylinder with a...Ch. 1.5 - Prob. 35PCh. 1.5 - In the course of pumping up a bicycle tire, a...Ch. 1.5 - Prob. 37PCh. 1.5 - Two identical bubbles of gas form at the bottom of...Ch. 1.5 - By applying Newtons laws to the oscillations of a...Ch. 1.5 - In problem 1.16 you calculated the pressure of...Ch. 1.6 - To measure the heat capacity of an object, all you...Ch. 1.6 - The specific heat capacity of Albertsons Rotini...Ch. 1.6 - Calculate the heat capacity of liquid water per...Ch. 1.6 - Prob. 44PCh. 1.6 - Prob. 45PCh. 1.6 - Measured heat capacities of solids and liquids are...Ch. 1.6 - Your 200-g cup of tea is boiling-hot. About how...Ch. 1.6 - When spring finally arrives in the mountains, the...Ch. 1.6 - Prob. 49PCh. 1.6 - Consider the combustion of one mole of methane...Ch. 1.6 - Use the data at the back of this book to determine...Ch. 1.6 - The enthalpy of combustion of a gallon (3.8...Ch. 1.6 - Look up the enthalpy of formation of atomic...Ch. 1.6 - Prob. 54PCh. 1.6 - Heat capacities are normally positive, but there...Ch. 1.7 - Calculate the rate of heat conduction through a...Ch. 1.7 - Home owners and builders discuss thermal...Ch. 1.7 - According to a standard reference table, the R...Ch. 1.7 - Make a rough estimate of the total rate or...Ch. 1.7 - A frying pan is quickly heated on the stovetop to...Ch. 1.7 - Geologists measure conductive heat flow out of the...Ch. 1.7 - Consider a uniform rod of material whose...Ch. 1.7 - Prob. 63PCh. 1.7 - Make a rough estimate of the thermal conductivity...Ch. 1.7 - Prob. 65PCh. 1.7 - In analogy with the thermal conductivity, derive...Ch. 1.7 - Make a rough estimate of how far food coloring (or...Ch. 1.7 - Prob. 68PCh. 1.7 - Imagine a narrow pipe, filled with fluid, in which...Ch. 1.7 - Prob. 70P
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- In Section 1.13 it was stated that the van der Waals constant b is approximately four times the volume occupied by the molecules themselves. Justify this relationship for a gas composed of spherical moleculesarrow_forward(b) Consider the following heat system on the real line: U - U = 0, XER, 1>0 %3D u(x, 0) = | sin x), rER. i. Use the fundamental solution of the heat equation to write down a solution u to the system above as an integral. ii. Show that the solution u that you have found is bounded by 1.arrow_forward2.2 Consider a van der Waal's gas that undergoes an isothermal expansion from volume V₁ to volume V₂. (a) (b) Calculate the change in the Helmholtz free energy. From the theory of thermodynamics, with 7 and V p. Show that the change in independent, (a) T V (OV)₁ = 7 (SP), ), internal energy is AU = a a (1/17 - 12/2). G V₂arrow_forward
- An ideal gas initially at P, V, and T, is taken through a cydle as shown below. (Let the factor n - 3.3.) P B P, V. (a) Find the net work done on the gas per cycle for 2.45 mol of gas initially at 0°C. kJ (b) What is the net energy added by heat to the system per cycle?arrow_forwardStatical Mechanics (Thermal and Statical Physics) Instruction: Write ALL the solutions of this (necessary or and not direct answer). Write also the equations that are needed to solve for a certain problem. Thank you. Problem: Now, we have the number of microstates and in between E and E + ∆E in isolated system of N particles in the volume V is given by: (Please see the image attached) Where a,b, c are constants. Note: Answer also letter A-Darrow_forward3.2. The simulation of parameter-distributed processes is connected with discretization in space and time. The distribution of changes in the temperature x of a heated at the front massive long metal piece is described by the following partial differential equation: Əx(z,t) F x(z,t) a[x(z,t) - 0,]+b- Əz? where 0, is the ambient temperature, a and b are constants. Derive the discrete model by applying discretization first with respect to z (z; = i.Az) and after that with respect to t (tx = k.At), using backward finite differences for the corresponding derivatives.arrow_forward
- Problem 1.2. The Rankine temperature scale (abbreviated °R) uses the same size degrees as Fahrenheit, but measured up from absolute zero like kelvin (so Rankine is to Fahrenheit as kelvin is to Celsius). Find the conversion formula between Rankine and Fahrenheit, and also between Rankine and kelvin. What is room temperature on the Rankine scale?arrow_forward1.9. Making use of the fact that the entropy S(N, V. E) of a thermodynamic system is an extensive quantity, show that N as ƏN V.E +V as av N.E + E as JE N.V Note that this result implies that (-Nu + PV + E)/T = S, that is, Nu = E + PV-TS. = S.arrow_forward1.1 A quantity of ideal monatomic gas consists of n molecules initially at temperature Ta. The pressure and volume are then slowly doubled in such a manner as to trace out a straight line on a p-V diagram. (a) In terms of n, R, and Ta, calculate: The work W (i) The internal energy AU (b) What would be the value of the molar specific heat for this process?arrow_forward
- For this question, consider a cylinder filled with a gas, com- pressed by a piston, as discussed in lectures. Consider the gas to be an ideal gas with constant heat capacity at fixed pressure (Cp) and constant heat capacity at fixed pressure (Cy). (See Tutorial 2). Both Cp and Cy are positive numbers. (a) How could we place this system into a state that is in mechanical equilibrium, but not in thermal equilibrium, with its surroundings? (b) We wish to raise the temperature of the gas isobarically (at constant pressure), and then lower the temperature isochorically (at constant volume). Briefly describe an experimental process that will achieve this. (c) The gas expands isobarically and reversibly from (Vo, Po, To) to (V₁, Po, T₁) — call this Process 1. Illustrate this process on a pV -diagram. (d) Calculate the amount work done on the gas during Process 1. Pay attention to the sign of your answer. (e) Show that the amount of heat that flows into the system during Process 1 is, V₁ - Vo…arrow_forwardUsing MATLAB editor, make a script m-file which includes a header block and comments: Utilizing the ideal gas law: Vmol= RT/P Calculate the molecular volume where: R = 0.08206 L-atm/(mol-K) P = 1.015 atm. and T = 270 - 315 K in 5 degree increments Make a display matrix which has the values of T in the first column and Vmol in the second column Save the script and publish function to create a pdf file from the script in a file named "ECE105_Wk2_L1_Prep_1"arrow_forwardProblem 1.18. Calculate the rms speed of a nitrogen molecule at room temperature.arrow_forward
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