Physics Laboratory Manual
4th Edition
ISBN: 9781133950639
Author: David Loyd
Publisher: Cengage Learning
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Chapter 25, Problem 1PLA
To determine
The description of
Expert Solution & Answer
Answer to Problem 1PLA
The equation of ideal
Explanation of Solution
Ideal gas law is the equation of state of gas which describes the relation between the pressure, volume, number of molecules and absolute temperature of gas in a closed system.
The gases that obey the ideal gas equation are called ideal gas.
Write the expression for the ideal gas equation
Here,
Conclusion:
Thus, the equation of ideal gas law is
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Chapter 25 Solutions
Physics Laboratory Manual
Ch. 25 - Prob. 1PLACh. 25 - What are the conditions under which a real gas...Ch. 25 - Prob. 3PLACh. 25 - Which temperature scale must always be used in the...Ch. 25 - The temperature in a room is measured to be Tc =...Ch. 25 - If the volume of the room in Question 5 is 50.0 m3...Ch. 25 - A gas at constant temperature has a volume of 25.0...Ch. 25 - A gas at constant pressure has a volume of 35.0 m3...
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- When we use the ideal gas law, the temperature must be in which of the following units? (5.6) (a) C (b) F (c) Karrow_forwardStarting with Equation 18.11, show that the total pressure P in a container filled with a mixture of several ideal gases is P=P1+P2+P3+, where P1,P2, are the pressures that each gas would exert if it alone filled the container. (These individual pressures are called the partial pressures of the respective gases.) This result is known as Daltons law of partial pressures.arrow_forwardHow do gases differ from liquids?arrow_forward
- A rigid lank contains 1.50 moles of an ideal gas. Determine the number of moles of gas that must be withdrawn from the lank to lower the pressure of the gas from 25.0 atm to 5.00 atm. Assume the volume of the tank and the temperature of the gas remain constant during this operation.arrow_forwardHow is momentum related to the pressure exerted by a gas? Explain on the atomic and molecular level, considering the behavior of atoms and molecules.arrow_forwardHelium gas is in thermal equilibrium with liquid helium at 4.20 K. Even though it is on the point of condensation, model the gas as ideal and determine the most probable speed of a helium atom (mass = 6.64 1027 kg) in it.arrow_forward
- . A booster pump on a brake system designed to be used horizontally consists of two cylinders capped by pistons connected by a hose. The cylinders and hose are filled with an incompressible fluid. The system produces a mechanical advantage of five times; that is, the output force is five times as great as the input force. If the cross-sectional area of the input piston is 4.0 in.2, how large must the area of the output piston be?arrow_forwardReview. This problem is a continuation of Problem 39 in Chapter 19. A hot-air balloon consists of an envelope of constant volume 400 m3. Not including tire air inside, the balloon and cargo have mass 200 kg. The air outside and originally inside is a diatomic ideal gas at 10.0C and 101 kPa, with density 1.25 kg/m3. A propane burner at the center of the spherical envelope injects energy into the air inside. The air inside stays at constant pressure. Hot air, at just the temperature required to make the balloon lift off, starts to fill the envelope at its closed top, rapidly enough so that negligible energy flows by heat to the cool air below it or out through the wall of the balloon. Air at 10C leaves through an opening at the bottom of the envelope until the whole balloon is filled with hot air at uniform temperature. Then the burner is shut off and the balloon rises from the ground. (a) Evaluate the quantity of energy the burner must transfer to the air in the balloon. (b) The heat value of propanethe internal energy released by burning each kilogramis 50.3 MJ/kg. What mass of propane must be burned?arrow_forwardReview. This problem is a continuation of Problem 16.29 in Chapter 16. A hot-air balloon consists of an envelope of constant volume 400 m3. Not including the air inside, the balloon and cargo have mass 200 kg. The air outside and originally inside is a diatomic ideal gas at 10.0C and 101 kPa, with density 1.25 kg/m3. A propane burner at the center of the spherical envelope injects energy into the air inside. The air inside stays at constant pressure. Hot air, at just the temperature required to make the balloon lift off, starts to fill the envelope at its closed top, rapidly enough so that negligible energy flows by heat to the cool air below it or out through the wall of the balloon. Air at 10C leaves through an opening at the bottom of the envelope until the whole balloon is filled with hot air at uniform temperature. Then the burner is shut off and the balloon rises from the ground. (a) Evaluate the quantity of energy the burner must transfer to the air in the balloon. (b) The heat value of propanethe internal energy released by burning each kilogramis 50.3 MJ/kg. What mass of propane must be burned?arrow_forward
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