Skip to main content
Ch. 6 - Applications of Integration
Briggs - Calculus: Early Transcendentals 3rd Edition
Briggs3rd EditionCalculus: Early TranscendentalsISBN: 9780136847243Not the one you use?Change textbook
All textbooksBriggs 3rd EditionCh. 6 - Applications of IntegrationProblem 6.1.47c
Chapter 6, Problem 6.1.47c

Depletion of natural resources Suppose r(t) = r0e^−kt, with k>0, is the rate at which a nation extracts oil, where r0=10⁷ barrels/yr is the current rate of extraction. Suppose also that the estimate of the total oil reserve is 2×10⁹ barrels. 


c. Find the minimum decay constant k for which the total oil reserves will last forever.

Verified step by step guidance
1
Understand the problem: The extraction rate is given by the function \(r(t) = r_0 e^{-kt}\), where \(r_0 = 10^7\) barrels/year and \(k > 0\) is the decay constant. The total oil reserve is \(2 \times 10^9\) barrels. We want to find the minimum value of \(k\) such that the total extracted oil over infinite time does not exceed the reserve.
Set up the integral for total oil extracted over time from \(t=0\) to \(t=\infty\): \(\displaystyle \int_0^{\infty} r(t) \, dt = \int_0^{\infty} r_0 e^{-kt} \, dt\).
Evaluate the integral: Since \(r_0\) is constant, factor it out: \(r_0 \int_0^{\infty} e^{-kt} \, dt\). The integral of \(e^{-kt}\) from 0 to infinity is \(\frac{1}{k}\), so the total extracted oil is \(\frac{r_0}{k}\).
Apply the condition that the total extracted oil must be less than or equal to the total reserve: \(\frac{r_0}{k} \leq 2 \times 10^9\) barrels.
Solve the inequality for \(k\): Rearranging gives \(k \geq \frac{r_0}{2 \times 10^9}\). Substitute \(r_0 = 10^7\) to find the minimum decay constant \(k\).

Verified video answer for a similar problem:

This video solution was recommended by our tutors as helpful for the problem above.
Video duration:
4m
Was this helpful?

Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Exponential Decay Function

An exponential decay function models quantities that decrease at a rate proportional to their current value. Here, r(t) = r0e^(-kt) represents the rate of oil extraction decreasing over time, where k > 0 controls how fast the rate declines. Understanding this helps analyze how extraction slows and affects total resource depletion.
Recommended video:
09:29
Exponential Growth & Decay

Definite Integral and Total Quantity Extracted

The total amount of oil extracted over time is found by integrating the rate function r(t) from zero to infinity. This integral sums all infinitesimal extractions, allowing us to compare the total extracted oil to the reserve limit. Mastery of definite integrals is essential to solve for conditions on k.
Recommended video:
05:43
Definition of the Definite Integral

Convergence of Improper Integrals

Since the extraction rate decreases exponentially, the integral from zero to infinity is an improper integral. Determining whether this integral converges (i.e., has a finite value) is crucial to ensure the total extracted oil does not exceed the reserve. This concept helps find the minimum decay constant k for sustainable extraction.
Recommended video:
11:11
Improper Integrals: Infinite Intervals
Related Practice
Textbook Question

Where do they meet? Kelly started at noon (t=0) riding a bike from Niwot to Berthoud, a distance of 20 km, with velocity v(t) = 15 / (t + 1)² (decreasing because of fatigue). Sandy started at noon (t=0) riding a bike in the opposite direction from Berthoud to Niwot with velocity u(t) = 20 / (t + 1)² (also decreasing because of fatigue). Assume distance is measured in kilometers and time is measured in hours.


c. When do they meet? How far has each person traveled when they meet?

Textbook Question

Probe speed A data collection probe is dropped from a stationary balloon, and it falls with a velocity (in m/s) given by v(t) = 9.8t, neglecting air resistance. After 10 s, a chute deploys and the probe immediately slows to a constant speed of 10 m/s, which it maintains until it enters the ocean.


c. If the probe was released from an altitude of 3 km, when does it enter the ocean?

Textbook Question

Oscillating growth rates Some species have growth rates that oscillate with an (approximately) constant period P. Consider the growth rate function N'(t) = r+A sin 2πt/P, where A and r are constants with units of individuals/yr, and t is measured in years. A species becomes extinct if its population ever reaches 0 after t=0.


c. Suppose P=10, A=50, and r=5. If the initial population is N(0)=10, does the population ever become extinct? Explain.

Textbook Question

13–16. Displacement from velocity Consider an object moving along a line with the given velocity v. Assume time t is measured in seconds and velocities have units of m/s.


c. Find the distance traveled over the given interval.


v(t) = 4t³ - 24t²+20t on [0, 5]

Textbook Question

Explain why or why not Determine whether the following statements are true and give an explanation or counterexample.


Arc length may be negative if f(x) < 0 on part of the interval in question.

Textbook Question

9–10. Velocity graphs The figures show velocity functions for motion along a line. Assume the motion begins with an initial position of s(0)=0. Determine the following.

c. The position at t=5