Using the ideal gas law with two unknowns

AI Thread Summary
The discussion revolves around applying the ideal gas law to a closed container of a single atom ideal gas undergoing volume expansion. Given initial conditions of volume, pressure, and temperature, the volume increases to eight times its original size. The user calculated the number of moles and attempted to find the new temperature using an adiabatic expansion formula, but their result of 221.46 K was deemed incorrect by their lecturer. Another participant suggested a temperature of 223 K, prompting curiosity about the lecturer's perspective on this answer. The conversation highlights the complexities of using the ideal gas law with multiple unknowns in thermodynamic processes.
kaffekjele
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Homework Statement



You are given a closed container containing a single atom ideal gas.
The volume is V1= 0,45*10^(-3) m^3
Pressure p1 is 3,2 MPa
Temperature, T1, is 892 K

The volume of the gas is increased to V2= 8*V1

Find the pressure and temperature after the increase of volume.


Homework Equations



Ideal gas equation pV=nRT





The Attempt at a Solution



I have n= 0,19 moles from a previous question. R is the ideal gas constant, 8,31 J/moles*K

Manipulating the ideal gas equation for pressure gives me p = (nRT)/V but that leaves T as an unknown so I'm not sure if that's the right way to go...
 
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I would expect that the expansion is adiabatic, this gives another constraint on the gas.
 
I was looking at that and tried to find the new temperature by using T2= T1*(\frac{V1}{V2})\gamma-1 which gave me 221,46K which is not correct according to my lecturer.
 
It would be interesting to see how the lecturer would solve this.
 
kaffekjele said:
I was looking at that and tried to find the new temperature by using T2= T1*(\frac{V1}{V2})\gamma-1 which gave me 221,46K which is not correct according to my lecturer.

I get 223 K. What does your lecturer think about that answer?
 
Thread 'Confusion regarding a chemical kinetics problem'

Thread 'Confusion regarding a chemical kinetics problem'

TL;DR Summary: cannot find out error in solution proposed. [![question with rate laws][1]][1] Now the rate law for the reaction (i.e reaction rate) can be written as: $$ R= k[N_2O_5] $$ my main question is, WHAT is this reaction equal to? what I mean here is, whether $$k[N_2O_5]= -d[N_2O_5]/dt$$ or is it $$k[N_2O_5]= -1/2 \frac{d}{dt} [N_2O_5] $$ ? The latter seems to be more apt, as the reaction rate must be -1/2 (disappearance rate of N2O5), which adheres to the stoichiometry of the...
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