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Chapter 6: Problem 49

A force in the \(+x\)-direction with magnitude \(F(x) = 18.0 \, \mathrm{N} - (0.530 \, \mathrm{N/m})x\) is applied to a 6.00-kg box that is sitting on the horizontal, frictionless surface of a frozen lake. \(F(x)\) is the only horizontal force on the box. If the box is initially at rest at \(x = 0\), what is its speed after it has traveled 14.0 m?

Short Answer

Expert verified
The speed of the box is approximately 6.06 m/s.

Step by step solution

01

Understand the Problem

We're given a force function that varies with position, \( F(x) = 18.0 \, \mathrm{N} - (0.530 \, \mathrm{N/m})x \). We need to find the speed of a 6.00-kg box after it travels 14.0 m starting from rest.
02

Find the Work Done by the Force

The work done by a variable force as an object moves from \( x = 0 \) to \( x = 14 \, \mathrm{m} \) can be calculated by integrating the force function:\[W = \int_{0}^{14} F(x) \, dx = \int_{0}^{14} \left( 18.0 - 0.530x \right) \, dx\]Calculate the integral to find the work done.
03

Calculate the Integral

Solve:\[W = \int_{0}^{14} (18.0 - 0.530x) \, dx \]This evaluates to:\[W = \left[ 18.0x - 0.530 \frac{x^2}{2} \right]_{0}^{14} = (18.0 \times 14) - 0.530 \times 7 \times (14)^2 \]Calculate this to find \( W = 110.0 \, \mathrm{J} \).
04

Apply the Work-Energy Principle

According to the work-energy principle, the work done on the box is equal to the change in kinetic energy:\[W = \Delta KE = \frac{1}{2} mv^2 - \frac{1}{2} m(0)^2 \]Substitute the work and solve for velocity \( v \).
05

Solve for the Final Velocity

We know:\[110.0 = \frac{1}{2} \times 6.0 \times v^2\]Rearrange to solve for \( v \):\[v^2 = \frac{110.0 \times 2}{6.0} = 36.67 \]\[v = \sqrt{36.67} \approx 6.06 \, \mathrm{m/s}\]
06

Conclusion

The speed of the box after it has traveled 14.0 m is approximately \( 6.06 \, \mathrm{m/s} \).

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Variable Force
In physics, when we talk about variable force, we refer to a force whose magnitude changes depending on certain factors, such as position, time, or velocity of the object it is acting upon. In the given exercise, the force is expressed as a function of position:
  • \( F(x) = 18.0 \; \mathrm{N} - (0.530 \; \mathrm{N/m})x \)
This equation means the force decreases as the position \( x \) increases. The more to the right the box moves, the lesser the force applied forward. This could be due to a medium's resistance, a sort of friction, or adjusting thrust.
To analyze such problems, we need to integrate the force over the distance. This process will help us calculate the work done by the force, which accounts for the 'changing nature' of variable forces. This way, we accommodate for how the force's magnitude contracts gradually as the box gets further along its path.
Kinetic Energy
Kinetic energy is the energy of motion. When an object moves, it has kinetic energy. Our exercise uses this idea prominently.
  • The relationship between work done by a force and kinetic energy is crucial.
  • Work-energy principle states: the work done on an object changes its kinetic energy.
For our box on a frictionless surface, the work done by the variable force as it moves from \( x = 0 \) to \( x = 14 \; \mathrm{m} \) is calculated using this principle.
Integrating the variable force over its path gives us the work done. The change in kinetic energy is given as, \[ W = \Delta KE = \frac{1}{2} mv^2 - \frac{1}{2} m(u)^2 \]Because the box starts from rest, \( u = 0 \), so the final kinetic energy equals the work done. This relationship helps us determine the box's speed after moving 14 meters.
In simpler terms, the work done by the force results in the box speeding up, and we can compute how fast by knowing the work put in and the box's mass.
Integral Calculus
Integral calculus is a branch of mathematics that deals with the concept of integration which allows us to determine quantities like area, volume, and in our case, work done by a force.
  • In this problem, the force changes with position, so we need to "add up" all the small contributions of force over the 14 m distance.
  • This is done using an integral to summarize the continuous accumulation of force.
The integral we compute is \[ W = \int_{0}^{14} (18.0 - 0.530x) \; dx \]This integral splits the problem into small segments over which we calculate force exerted and multiplied by the distance traveled.
Once integrated, it provides the total work done on the box across the whole path from 0 to 14 meters. This result allows us to apply the work-energy principle effectively, transitioning us from mathematical calculations to physical predictions of motion outcomes.
Understanding integration in this context is pivotal because it transforms the question of "How much force is applied?" into a nuanced answer where force continuously changes, yet yields a precise work value. This can be especially insightful for students who need to tackle problems where forces are not constant.

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Most popular questions from this chapter

The Grand Coulee Dam is 1270 m long and 170 m high. The electrical power output from generators at its base is approximately 2000 MW. How many cubic meters of water must flow from the top of the dam per second to produce this amount of power if 92% of the work done on the water by gravity is converted to electrical energy? (Each cubic meter of water has a mass of 1000 kg.)

A small block with a mass of 0.0600 kg is attached to a cord passing through a hole in a frictionless, horizontal surface (\(\textbf{Fig. P6.71}\)). The block is originally revolving at a distance of 0.40 m from the hole with a speed of 0.70 m/s. The cord is then pulled from below, shortening the radius of the circle in which the block revolves to 0.10 m. At this new distance, the speed of the block is 2.80 m/s. (a) What is the tension in the cord in the original situation, when the block has speed \(\upsilon = 0.70\) m/s? (b) What is the tension in the cord in the final situation, when the block has speed \(\upsilon = 2.80\) m/s? (c) How much work was done by the person who pulled on the cord?

On December 27, 2004, astronomers observed the greatest flash of light ever recorded from outside the solar system. It came from the highly magnetic neutron star SGR 1806-20 (a \(magnetar\)). During 0.20 s, this star released as much energy as our sun does in 250,000 years. If \(P\) is the average power output of our sun, what was the average power output (in terms of \(P\)) of this magnetar?

Three identical 8.50-kg masses are hung by three identical springs (\(\textbf{Fig. E6.35}\)). Each spring has a force constant of 7.80 kN/m and was 12.0 cm long before any masses were attached to it. (a) Draw a free-body diagram of each mass. (b) How long is each spring when hanging as shown? (\(Hint\): First isolate only the bottom mass. Then treat the bottom two masses as a system. Finally, treat all three masses as a system.)

An airplane in flight is subject to an air resistance force proportional to the square of its speed v. But there is an additional resistive force because the airplane has wings. Air flowing over the wings is pushed down and slightly forward, so from Newton's third law the air exerts a force on the wings and airplane that is up and slightly backward (\(\textbf{Fig. P6.94}\)). The upward force is the lift force that keeps the airplane aloft, and the backward force is called \(induced \, drag\). At flying speeds, induced drag is inversely proportional to \(v^2\), so the total air resistance force can be expressed by \(F_air = \alpha v^{2} + \beta /v{^2}\), where \(\alpha\) and \(\beta\) are positive constants that depend on the shape and size of the airplane and the density of the air. For a Cessna 150, a small single-engine airplane, \(\alpha = 0.30 \, \mathrm{N} \cdot \mathrm{s^{2}/m^{2}}\) and \(\beta = 3.5 \times 10^5 \, \mathrm{N} \cdot \mathrm{m^2/s^2}\). In steady flight, the engine must provide a forward force that exactly balances the air resistance force. (a) Calculate the speed (in km/h) at which this airplane will have the maximum \(range\) (that is, travel the greatest distance) for a given quantity of fuel. (b) Calculate the speed (in km/h) for which the airplane will have the maximum \(endurance\)(that is, remain in the air the longest time).
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