An adult takes 400 milligrams (mg) of ibuprofen. Each hour, the amount of ibuprofen in the person's system decreases by one-fourth. Write the function that models the exponential change between the number of hours, [tex]t[/tex], and the number of milligrams of ibuprofen remaining in the person's system, [tex]m(t)[/tex].

A. [tex]m(t) = 400 \cdot 4^t[/tex]
B. [tex]m(t) = -400 - 4^t[/tex]
C. [tex]m(t) = -400 \cdot \left(\frac{1}{4}\right)^t[/tex]
D. [tex]m(t) = 400 \cdot \left(\frac{1}{4}\right)^t[/tex]



Answer :

To model the exponential decay of ibuprofen in an adult's system, we need a function that relates the amount of ibuprofen remaining, [tex]\( m(t) \)[/tex], to the time in hours, [tex]\( t \)[/tex].

Let's break down the problem step-by-step:

1. Initial Dose: The initial amount of ibuprofen taken is 400 milligrams (mg). This means at [tex]\( t = 0 \)[/tex] (the moment the adult takes the dose), [tex]\( m(0) = 400 \)[/tex].

2. Decay Rate: Each hour, the amount of ibuprofen decreases by one-fourth. This implies that after each hour, only [tex]\( \frac{1}{4} \)[/tex] (or 25%) of the previous amount remains. Therefore, we can conclude that the decay rate (fraction of the amount that remains from hour to hour) is [tex]\( \frac{1}{4} \)[/tex].

3. Exponential Function Form: Since this is an exponential decay problem, the general form of the function is:
[tex]\[ m(t) = \text{initial amount} \times (\text{decay rate})^t \][/tex]

4. Substituting Values: The initial amount is 400 mg, and the decay rate is [tex]\( \frac{1}{4} \)[/tex]. Placing these values into the general form, we get:
[tex]\[ m(t) = 400 \times \left(\frac{1}{4}\right)^t \][/tex]

Therefore, the function that models the exponential decay of ibuprofen in the person's system is:
[tex]\[ m(t) = 400 \cdot \left(\frac{1}{4}\right)^t \][/tex]

So the correct function among the given options is:
[tex]\[ m(t) = 400 \cdot \left(\frac{1}{4}\right)^t \][/tex]