The population of an endangered species of insect is 480,000. The population decreases at the rate of 10% per year. Identify the exponential decay function to model the situation. Then find the population of the species after 3 years.

A: y = 480,000 (1.01) t; 280,000

B: y = 480,000 (1.1) t; 638,880

C: y = 480,000 (0.9) t; 339,940

D: y = 480,000 (0.9) t; 349,920 5

Cesium-137 has a half-life of 30 years. Identify the amount of cesium-137 left from a 150 milligram sample after 120 years.

A: 0.9375 mg

B: 9.3750 mg

C: 1.097 mg

D: 1.325 mg 6

Question

Mathematics

Lyla

5 March, 23:55

The population of an endangered species of insect is 480,000. The population decreases at the rate of 10% per year. Identify the exponential decay function to model the situation. Then find the population of the species after 3 years.

A: y = 480,000 (1.01) t; 280,000

B: y = 480,000 (1.1) t; 638,880

C: y = 480,000 (0.9) t; 339,940

D: y = 480,000 (0.9) t; 349,920 5

Cesium-137 has a half-life of 30 years. Identify the amount of cesium-137 left from a 150 milligram sample after 120 years.

A: 0.9375 mg

B: 9.3750 mg

C: 1.097 mg

D: 1.325 mg 6

+5

Answers (1)

Know the Answer?

Brooke Cruz · Answer 1

D: y = 480,000 (0.9) t; 349,920

Step-by-step explanation:

The question requires us to model a compounding exponential decay function at a given rate for a particular period:

Using the model:

F = Fo (1 - r) ^t

Where;

F = final amount; Fo = Initial amount; r = annual rate; t = period

Initial amount = 480,000

Rate = 10%

t = 3years

F = 480,000 (1 - 0.1) ^3

F = 480,000 (0.9) ^3

F = 480,000 * 0.729

F = 349, 920

A = (Ao / 2^ (t/t1/2)

A = final amount

Ao = Initial amount

t = time or period; t1/2 = half-life = 30 years

A = (150 / 2^ (120/30))

A = (150 / 2^ (4))

A = 150/16

A = 9.375mg