The population of a colony of mosquitoes obeys the law of uninhibited growth

The population of a colony of mosquitoes obeys the law of uninhibited growth: Use this information to answer parts (a) through (c): (a) If N is the population of the colony and t is the time in days, express N as a function of t. Consider No is the original amount at t = 0 and k # 0 is a constant that represents the growth rate. N(t) = (Type an expression using t as the variable and in terms of e.) (b) The population of a colony of mosquitoes obeys the law of uninhibited growth. If there are 1000 mosquitoes initially and there are 1500 after day; what is the size of the colony after 4 days? Approximately mosquitoes (Do not round until the final answer: Then round to the nearest whole number as needed ) (c) How long is it until there are 40,000 mosquitoes? About days (Do not round until the final answer: Then round to the nearest tenth as needed )

The Correct Answer and Explanation is:

Part (a): Express N(t)N(t)N(t) as a function of ttt

The law of uninhibited growth for a population N(t)N(t)N(t) is modeled by the exponential growth equation:N(t)=N0ektN(t) = N_0 e^{kt}N(t)=N0​ekt

Where:

• N(t)N(t)N(t) is the population at time ttt,
• N0N_0N0​ is the initial population at t=0t = 0t=0,
• kkk is the growth rate constant,
• eee is the base of the natural logarithm.

This equation describes how the population grows over time if there are no restrictions on growth.

Part (b): Population after 4 days

We are given:

• Initial population N0=1000N_0 = 1000N0​=1000,
• After 1 day, the population is 1500.

We need to find the value of kkk and use that to determine the population after 4 days.

1. Step 1: Find the growth rate constant kkk:

Using the information that the population is 1500 after 1 day, we substitute into the formula:1500=1000ek⋅11500 = 1000 e^{k \cdot 1}1500=1000ek⋅1

Solving for kkk:15001000=ek\frac{1500}{1000} = e^k10001500​=ek1.5=ek1.5 = e^k1.5=ek

Taking the natural logarithm of both sides:ln⁡(1.5)=k\ln(1.5) = kln(1.5)=kk≈0.4055k \approx 0.4055k≈0.4055

2. Step 2: Find the population after 4 days:

Now that we know k≈0.4055k \approx 0.4055k≈0.4055, we can use the formula to find the population after 4 days:N(4)=1000e0.4055⋅4N(4) = 1000 e^{0.4055 \cdot 4}N(4)=1000e0.4055⋅4N(4)=1000e1.6222N(4) = 1000 e^{1.6222}N(4)=1000e1.6222N(4)≈1000×5.080N(4) \approx 1000 \times 5.080N(4)≈1000×5.080N(4)≈5080 mosquitoesN(4) \approx 5080 \text{ mosquitoes}N(4)≈5080 mosquitoes

Part (c): Time until the population reaches 40,000 mosquitoes

We are asked to find the time ttt when the population reaches 40,000. Using the same formula:40,000=1000e0.4055⋅t40,000 = 1000 e^{0.4055 \cdot t}40,000=1000e0.4055⋅t

1. Step 1: Solve for ttt:

40,0001000=e0.4055⋅t\frac{40,000}{1000} = e^{0.4055 \cdot t}100040,000​=e0.4055⋅t40=e0.4055⋅t40 = e^{0.4055 \cdot t}40=e0.4055⋅t

Taking the natural logarithm of both sides:ln⁡(40)=0.4055⋅t\ln(40) = 0.4055 \cdot tln(40)=0.4055⋅tt=ln⁡(40)0.4055t = \frac{\ln(40)}{0.4055}t=0.4055ln(40)​t≈3.68890.4055t \approx \frac{3.6889}{0.4055}t≈0.40553.6889​t≈9.1 dayst \approx 9.1 \text{ days}t≈9.1 days

Final Answers:

• (a) The population function is N(t)=N0ektN(t) = N_0 e^{kt}N(t)=N0​ekt.
• (b) The population after 4 days is approximately 5080 mosquitoes.
• (c) It will take approximately 9.1 days for the population to reach 40,000 mosquitoes.