The reaction is given as follows:
[tex]cyclopropane (g)\rightarrow propene (g)[/tex]
The plot of ln[cyclopropane] verses t is linear with slope [tex]-0.00067 s^{-1}[/tex].
The plot for ln[cyclopropane] verses t is linear for first order reaction (as in the diagram attached). The integrated rate law equation is as follows:
[tex][A]=[A_{0}]e^{-kt}[/tex]
Here, k is rate constant, t is time of the reaction, [tex][A][/tex] is concentration of reactant at time t and [tex][A_{0}][/tex] is initial concentration of reactant.
Taking ln both sides,
[tex]ln[A]=ln[A_{0}]-kt[/tex]
Comparing with equation for linear graph, y=mx+c
Thus, slope =-k
Or, [tex]k=0.00067 s^{-1}[/tex].
Therefore, order of the reaction is first and rate constant is [tex]0.00067 s^{-1}[/tex].
Answer:
1. 1st order chemical reaction.
2. [tex]k=0.00067 s^{-1}[/tex].
Explanation:
Hello,
In this case, as long as the information states that when graphing the ln[cyclopropane] vs time a straight line is obtained, one infers that it is about a first order chemical reaction, this could be substantiated via the integration of the rate law:
[tex]\frac{dC_C}{dt}=-k C_C^n[/tex]
If we set n=1, we are going to obtain the aforesaid logarithm as shown below:
[tex]\int\limits^{C_{C}}_{C_{C_0}} {\frac{1}{C_C} } \, dC_C=-k\int\limits^t_0 {} \, dt \\ ln(\frac{C_{C}}{C_{C_0}} )=-kt[/tex]
In such a way, the straight line accounts for the rate constant including the negative sign (cyclopropane's consumption), thus, the rate constant is:
[tex]k=-(-0.00067 s^{-1})\\k=0.00067 s^{-1}[/tex]
Which matches with a 1st order constant rate because of its units.
Best regards,
