10.) An ideal gas with goes thru the quasistatic cycle shown to the right. The Pabs(atm) steps are: A. Isothermal expansion from state 1 to state 2. B. Constant pressure compression from 2 to 3. C. Constant volume increase in pressure from 3 7.00 back to 1. a) Find the net change in internal energy of the gas for the complete cycle. b) Find the net heat exchanged by the gas with its surroundings. Is this heat into or out of the gas? c) Find the net work done by the gas for the complete cycle. Hint: Remember Q = nCvAT(const. volume) & Q = nCpAT(const. Pressure) 3.11 3: В V(L) 4.00 9.00

10.) An ideal gas with goes thru the quasistatic cycle shown to the right. The Pabs(atm) steps are: A. Isothermal expansion from state 1 to state 2. B. Constant pressure compression from 2 to 3. C. Constant volume increase in pressure from 3 7.00 back to 1. a) Find the net change in internal energy of the gas for the complete cycle. b) Find the net heat exchanged by the gas with its surroundings. Is this heat into or out of the gas? c) Find the net work done by the gas for the complete cycle. Hint: Remember Q = nCvAT(const. volume) & Q = nCpAT(const. Pressure) 3.11 3: В V(L) 4.00 9.00

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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Question

10.) An ideal gas with goes thru the
quasistatic cycle shown to the right. The
Pabs(atm)
steps are:
A. Isothermal expansion from state 1 to state 2.
B. Constant pressure compression from 2 to 3.
C. Constant volume increase in pressure from 3
7.00
back to 1.
a) Find the net change in internal energy of the
gas for the complete cycle.
b) Find the net heat exchanged by the gas with
its surroundings. Is this heat into or out of
the gas?
c) Find the net work done by the gas for the complete cycle.
Hint: Remember Q = nCvAT(const. volume) & Q = nCpAT(const. Pressure)
3.11
3:
В
V(L)
4.00
9.00

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