ZuoTi.Pro
Question

In this problem you are to consider an adiabaticexpansion of an ideal diatomic gas, which means...

In this problem you are to consider an adiabaticexpansion of an ideal diatomic gas, which means that the gas expands with no addition or subtraction of heat.

Assume that the gas is initially at pressure p0, volume V0, and temperature T0. In addition, assume that the temperature of the gas is such that you can neglect vibrational degrees of freedom. Thus, the ratio of heat capacities is γ=Cp/CV=7/5.

Note that, unless explicitly stated, the variable γ should not appear in your answers--if needed use the fact that γ=7/5 for an ideal diatomic gas.

Part A

Find an analytic expression for p(V), the pressure as a function of volume, during the adiabatic expansion.

Express the pressure in terms of V and any or all of the given initial values p0, T0, and V0.

Correct

p(V) =

p0(V0V)75

Part B

At the end of the adiabatic expansion, the gas fills a new volume V1, where V1>V0. Find W, the work done by the gas on the container during the expansion.

Express the work in terms of p0, V0, and V1. Your answer should not depend on temperature.

Part C

Find ΔU, the change of internal energy of the gas during the adiabatic expansion from volume V0 to volume V1.

Express the change of internal energy in terms of p0, V0, and/or V1.

Need Part B and C

science   physics   
0 0
Add a comment Improve this question Transcribed image text
Next > < Previous
Sort answers by oldest

Homework Answers

✔ Recommended Answer
Answer #1

Here we apply thermodynamics first law and definition of adiabatic process and work done.

Building A(A We trow fr adiabadic poces Iniha paesure valume Temperadure Vo To Preure P at valume V PV Pa P Po aloxk done, JBuilding Work done by the gau contalnex duing expanaon VD (eChanje ininternal enex gy AU ATE T-To PoVo he AT AT np Nou P 3 STBuilding Work done by the gau contalnex duing expanaon VD (eChanje ininternal enex gy AU ATE T-To PoVo he AT AT np Nou P 3 ST

0 0
Add a comment
Know the answer?
Add Answer to:
In this problem you are to consider an adiabaticexpansion of an ideal diatomic gas, which means...
Your Answer:

Post as a guest

Your Name:

What's your source?

Earn Coins

Coins can be redeemed for fabulous gifts.

Log In

Sign Up

Similar Homework Help Questions

  • Item 10 In this problem you are to consider an adiabatic expansion of an ideal diatomic...

    Item 10 In this problem you are to consider an adiabatic expansion of an ideal diatomic gas, which means that the gas expands with no addition or subtraction of heat. Part A Assume that the gas is initially at pressure Po, volume V. and temperature To. In addition, assume that the temperature of the gas is such that you can neglect vibrational degrees of freedom. Thus, the ratio of heat capacities is y=Cp/Cy = 7/5. Find an analytic expression for...

  • Consider n moles of ideal gas kept in a heat-isolated cylinder (all processes are adiabatic) with...

    Consider n moles of ideal gas kept in a heat-isolated cylinder (all processes are adiabatic) with a piston at external pressure p0, and at temperature T0. The external pressure is suddenly changed to p=2p0, and we wait for the system to equilibrate. The volume and the temperature of the ideal gas after equilibration is V and T, respectively. a) Calculate the amount w of work produced on the system in terms of p, p0, V, T0, and n. Using the...

  • Assume air can be modeled as an ideal, diatomic gas. Given n moles of air at...

    Assume air can be modeled as an ideal, diatomic gas. Given n moles of air at temperature T0 and pressure p0, how much energy must be expended as work to compress it to one tenth of its original volume, if a) the compression occurs along an isotherm? b) the compression occurs along a reversible adiabatic path? c) Evaluate your results to parts (a) and (b) for n = 5.00 mol, T0 = 20.0 ◦C, and p0 = 1.00 atm. Express...

  • Now consider a sample of 1 mole of a diatomic ideal gas that is initially at...

    Now consider a sample of 1 mole of a diatomic ideal gas that is initially at a temperature of 265 kelvin and volume of .2 m^3. The gas first undergoes an isobaric expansion, such that its temperature increases by 120 kelvin. It then undergoes an adiabatic expansion so that its final volume is .360 m^3 a) What is the initial pressure of the gas, in kPa? b) What is the total heat transfer, Q, to the gas, in J? c)...

  • A 0.450-mol sample of an ideal diatomic gas at 372 kPa and 312 K expands quasi-statically

    A 0.450-mol sample of an ideal diatomic gas at 372 kPa and 312 K expands quasi-statically until the pressure decreases to 147 kPa. Find the final temperature and volume of the gas, the work done by the gas, and the heat absorbed by the gas if the expansion is the following. (a) Isothermal final temperature _______  volume of the gas _______  work done by the gas _______  heat absorbed _______  (b) adiabatic final temperature _______  volume of the gas _______  work done by the gas _______  heat absorbed _______ 

  • Cycles in a heat engine The basic idea of a heat engine is to add heat...

    Cycles in a heat engine The basic idea of a heat engine is to add heat to a gas, and have the gas perform work on its environment via an expansion, which in turn is used to power motion. The gas is then restored to its original temperature and the cycle begins again. You can assume that the same amount of gas remains in the engine during the cycle. A convenient way to think about these cycles is a pressure...

  • Consider a monoatomic ideal gas undergoing the following cycle: starting point (a), pressure increases at a...

    Consider a monoatomic ideal gas undergoing the following cycle: starting point (a), pressure increases at a constant volume reaching point (b), then the gas expands adiabatically until pressure reaches the initial value (point c), and then the gas is compressed at a constant pressure until the volume reaches the initial value back to point (a). The amount of gas is 1 mole. Monoatomic gas means it has only 3 degrees of freedom and the adiabatic constant gamma is 5/3. Sketch...

  • A Carnot cycle is conducted using an ideal diatomic gas. Initially, the gas is at temperature...

    A Carnot cycle is conducted using an ideal diatomic gas. Initially, the gas is at temperature 25C., pressure of 100KPa and volume of 0.01m3. The system is then compressed isothermally to a volume 0.002m3. From that point, the gas undergoes an adiabatic compression ( with gamma= 1.4), until the volume further reduces to 0.001m3. After that, the system goes an isothermal expansion process to a point where the pressure of the system is 263.8KPa. Then the system continues the cycle...

  • We have a diatomic ideal gas with a y of 5/2. It starts with an initial...

    We have a diatomic ideal gas with a y of 5/2. It starts with an initial pressure of 1kPa, an initial temperature of 100 K, and an initial volume of 10 m^3 a) The gas undergoes an adiabatic compression, halving its volume. What is its new pressure? b) What was the work done? c) What was the heat flow? d) Now, keeping pressure constant, heat is put into the gas, doubling the volume. How much heat is added? e) What...

  • Part A:See diagram 4. 51.4 moles of a diatomic ideal gas undergo three steps: A to...

    Part A:See diagram 4. 51.4 moles of a diatomic ideal gas undergo three steps: A to B is an isobaric (constant pressure P1 = 5.64x106 Pascal) expansion from volume V1 = 0.0854 m3 to V2 = 0.979 m3. B to C is isochoric (constant volume) C to A is isothermal (constant T). Find PC, the pressure at point C, in Pascals. Express in scientific notation. Part B:See diagram 4. 21.6 moles of a diatomic ideal gas undergo three steps: A...

ADVERTISEMENT
Free Homework Help App
Download From Google Play
Scan Your Homework
to Get Instant Free Answers
Need Online Homework Help?
Ask a Question
Get Answers For Free
Most questions answered within 3 hours.
ADVERTISEMENT
ADVERTISEMENT
ADVERTISEMENT