Answer:
The answers to this question and its part is given in details in the explanatory section below. But highlights to the answers are as follows -
[a] please see attachment
[b] - Â W = 207.85J
[c] - The work done is primarily on the friction less piston of the gas cylinder.
[d] - 711.5J
[e] - 919.35J
[f] - unchanged
Explanation:
Before kicking off in answering the questions, one needs to extract the relevant information needed. From the question, one can notice that there was an increase in temperature from 27°C to 127°C which in turn happened at a constant pressure of 1.00 atm. Therefore, in accordance to the ideal gas law, the volume of a gas will increase with a corresponding increase in temperature. Â
[a]
With the already established point above, the pressure - volume (pV) diagram for the process is as follows;
See attachment to the diagram.
[b]
At constant pressure, the work done by the gas is expressed as -
       [tex]W = p[/tex]ΔV  ------------------------ (i)
where  W = work done
       p = pressure
     ΔV = change in volume
Since ΔV was not given as a parameter in the question, one needs to calculate for this value first. From an ideal gas law, we have -
        pV = nRT -----------------------(ii)
where,
        R = ideal gas constant = 8.314 J/mol.K
        n = 0.250 mol
        T = Temperature
       pΔV = nRΔT
       ΔV = (nR/p) ΔT
Now substituting the value of ΔV in equation (i) we have
       W = p (nR/p) ΔT  ---------------------- (iii)
by mere looking at equation (iii) once will notice that p cancels out each other, the new equation becomes
       W =  nR ΔT
       where  ΔT = ( T2 - T1)
                T2 = 127°C = 400°K
                T1 = 27°C = 300°K
            W = 0.250 mol * 8.314 J/mol.K (400 - 300)
            W = 207.85J
[c]
The work done is primarily on the friction less piston of the gas cylinder.
[d] Since the internal energy witnessed by the gas depends on the applied temperature, hence, it can be calculated as follows -
         ΔU = n [tex]C_{v}[/tex]ΔT -------------------- (iv)
where,
      [tex]C_{v}[/tex] = molar heat specific capacity at constant volume for Carbon di     oxide = 28.46 J/mol.K
calculating for ΔU we have
        ΔU = 0.250 mol * 28.46 J/mol.K (400 -300)
           =  711.5J
[e]
To know how much heat was supplied to the gas, we need to apply the first law of thermodynamics -
        Q = ΔU + W --------------------- (v)
          = 711.5 + 207.85
          = 919.35J
[f]
Since the work done does not depend on the pressure, therefore, a reduction of the pressure from its constant state of 1.00 atm to 0.50 atm will leave the result gotten for the work done in [b] unchanged.
