In diluted solution and with neutral pH, the reaction reacts according to a reaction velocity law of pseudo-1. order:
$$-\frac{dc_{DNPA}}{dt}=k_{obs},\quad k_{obs}=k\cdot c_{H_2O}$$
At $t=0$ we have $96\mu M$ DNPA.
How big is the concentration of DNPA and DNP after three half-time periods ($3\cdot t_{1/2}$)?
Of course, for DNPA we would just have $1/8$th of $96\mu M$ which is $12\mu M$. But what about DNP?
For me it's clear that it correlates directly with the concentration of DNPA since we have a heavy diluted solution, so the concentration of the water can be assumed as constant.
Further I know that $v_c(t)=\frac{1}{\nu_i}\frac{dd_i(t)}{dt}$ whereas $\nu_i$ are the stoichiometric coefficients. So basically, the concentration od DNPA, DNP and HOAc are the same since all have a stoichiometric coefficient of 1. Right? So they all change the same. Meaning: if DNPA changes to $1/8$-th, so does DNP and HOAc.
I am still a bit unsure, but can I now conclude, that $c_{DNP}(3t_{1/2})=12\mu M$?