Respuesta :
Answer:
a) 16.2 dm^3/mol*h
b) 6.1 × 10^3 s, 2.5 × 10^3 s (it is different to the hint)
Explanation:
We can use the integrated rate equation in order to obtain k.
For the reaction A+ B --> P the reaction rate is written as
Rate = [tex]-\frac{dC_A}{dt} = -\frac{dC_B}{dt} = \frac{dC_P}{dt} = kC_AC_B[/tex]
If [tex]C_{A0}[/tex] and [tex]C_{B0}[/tex] are the inital concentrations and x the concentration reacted at time t, so [tex]C_A=C_{A0} -x[/tex] and [tex]C_B=C_{B0} -x[/tex] and the rate at time t is written as:
[tex]-\frac{dx}{dt} =-k(C_{A0} -x)(C_{B0}-x)[/tex]
Separating variables and integrating
[tex]\int\limits^x_0 {\frac{1}{(C_{A0}-x)(C_{B0}-x)} } \, dx = \int\limits^t_0 {k} \, dt[/tex]
The integral in left side is solved by partial fractions, it can be used integral tables
[tex]\frac{1}{C_{B0}-C_{A0}}(ln\frac{C_{A0}}{C_{A0}-x}-ln\frac{C_{B0}}{C_{B0}-x}) =kt[/tex]
Using logarithm properties (ln x - ln y = ln(x/y))
[tex]\frac{1}{C_{B0}-C_{A0}}(ln\frac{C_{A0}C_{B}}{C_{A}C_{B0}}) =kt[/tex]
Using the given values k can be calculated. But the data seems inconsistent since if the concentration of A changes from 0.075 to 0.02 mol dm^-3 it implies that 0.055 mol dm^-3 of A have reacted after 1 h, so according to the reaction given the same quantity of B should react, and we only have a [tex]C_{B0}[/tex] of 0.05 mol dm^-3.
Assuming that the concentration of B fall to 0.02 mol dm^-3 (and not the concentration the A). So we arrive to the answer given in the Hint.
So, the values given are t= 1, [tex]C_{A0}=0.075[/tex], [tex]C_{B0}=0.05[/tex], [tex]C_{B}=0.02[/tex], it implies that the quantity reacted, x, is 0.03 and [tex]C_{A}=0.075-x = 0.045[/tex]. Then, the value of k would be
[tex]kt = \frac{1}{0.05-0.075}(ln\frac{0.075*0.02}{0.045*0.05}) [/tex]
[tex]k = 16.21 \frac{dm^3}{mol*1h}[/tex]
b) the question b requires calculate the time when the concentration of the specie is half of the initial concentration.
For reactant A, It is solved with the same equation
[tex]\frac{1}{C_{B0}-C_{A0}}(ln\frac{C_{A0}C_{B}}{C_{A}C_{B0}}) =kt[/tex]
but suppossing that [tex]C_A= C_{A0}/2=0.0375[/tex] so [tex]C_B=C_{B0}- C_{A0}/2=0.0125[/tex], k=16.2 and the same initial concentrations. Replacing in the equation
[tex]t=\frac{1}{16.2(0.05-0.075)}(ln\frac{0.075*0.0125}{0.0375*0.05})[/tex]
[tex] t=1.71 h = 1.71*3600 s = 6.1*10^3 s [/tex]
For reactant B, [tex]C_B= C_{B0}/2=0.025[/tex] so [tex]C_A=C_{A0}- C_{B0}/2=0.05[/tex], k=16.2 and the same initial concentrations. Replacing in the equation
[tex]t=\frac{1}{16.2(0.05-0.075)}(ln\frac{0.075*0.025}{0.05*0.05}) [/tex]
[tex] t=0.71 h = 0.7*3600 s = 2.5*10^3 s [/tex]
Note: The procedure presented is correct, despite of the answer be something different to the given in the hint, I obtain that result if the k is 19.2... (maybe an error in calculation of given numbers)
