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Chapter 7: Problem 43

A satellite with a mass of \(274 \mathrm{~kg}\) approaches a large planet at a speed \(v_{i, 1}=13.5 \mathrm{~km} / \mathrm{s}\). The planet is moving at a speed \(v_{i, 2}=10.5 \mathrm{~km} / \mathrm{s}\) in the opposite direction. The satellite partially orbits the planet and then moves away from the planet in a direction opposite to its original direction (see the figure). If this interaction is assumed to approximate an elastic collision in one dimension, what is the speed of the satellite after the collision? This so-called slingshot effect is often used to accelerate space probes for journeys to distance parts of the solar system (see Chapter 12).

Short Answer

Expert verified
After an elastic collision with a much larger planet, the final speed of the satellite is approximately 22,350 m/s.

Step by step solution

01

Convert speeds to the same units

To solve the problem, first convert the given speeds from km/s to m/s: $$ v_{i, 1} = 13.5 \frac{\mathrm{km}}{\mathrm{s}} \times \frac{1000 \mathrm{m}}{1 \mathrm{km}} = 13500 \frac{\mathrm{m}}{\mathrm{s}} $$ $$ v_{i, 2} = 10.5 \frac{\mathrm{km}}{\mathrm{s}} \times \frac{1000 \mathrm{m}}{1 \mathrm{km}} = 10500 \frac{\mathrm{m}}{\mathrm{s}} $$ Now the speeds are in the same units.
02

Apply linear momentum conservation

The first principle to apply is the conservation of linear momentum. The linear momentum before the collision is equal to the linear momentum after the collision. First, consider the satellite's linear momentum: $$ m_1v_{i, 1} + m_2v_{i, 2} = m_1v_{f, 1} + m_2v_{f, 2} $$ In this problem, we are only interested in the final speed of the satellite (i.e. \(v_{f, 1}\)). We also know that the planet is much larger and heavier than the satellite, so we can assume its speed remains almost unchanged after the collision. Thus, \(v_{f, 2} \approx v_{i, 2}\). Therefore, we can rewrite the above equation as: $$ v_{f, 1} = \frac{m_1v_{i, 1} + m_2(v_{i, 2} - v_{f, 2})}{m_1} $$
03

Apply kinetic energy conservation

The second principle to apply is the conservation of kinetic energy. The kinetic energy before the collision (initial) is equal to the kinetic energy after the collision (final): $$ \frac{1}{2} m_1v_{i, 1}^2 + \frac{1}{2} m_2v_{i, 2}^2 = \frac{1}{2} m_1v_{f, 1}^2 + \frac{1}{2} m_2v_{f, 2}^2 $$ As we assumed in Step 2 that the planet's speed remains unchanged, we can rewrite the kinetic energy equation as: $$ \frac{1}{2} m_1(v_{i, 1}^2 - v_{f, 1}^2) = \frac{1}{2} m_2(v_{f, 2}^2 - v_{i, 2}^2) $$
04

Solve for the final velocity of the satellite

Now, we have 2 equations with 2 variables (\(v_{f, 1}\) and \(v_{f, 2}\)) and we need to solve for \(v_{f, 1}\). To simplify the expression, notice that the linear momentum equation (Step 2) can be rewritten as: $$ v_{f, 2} = v_{i, 2} + \frac{m_1(v_{i, 1} - v_{f, 1})}{m_2} $$ Plug this expression into the kinetic energy equation (Step 3): $$ \frac{1}{2} m_1(v_{i, 1}^2 - v_{f, 1}^2) = \frac{1}{2} m_2\left(v_{i, 2} + \frac{m_1(v_{i, 1} - v_{f, 1})}{m_2}\right)^2 - \frac{1}{2} m_2v_{i, 2}^2 $$ After simplifying and solving the equation for \(v_{f, 1}\), we find: $$ v_{f, 1} = \frac{(2m_1+m_2)v_{i, 1} - m_2v_{i, 2}}{2m_1} $$ Now plug in the known values: $$ v_{f, 1} = \frac{(2(274 \,\mathrm{kg})+(274 \,\mathrm{kg}))(13500 \,\mathrm{m/s}) - (274 \,\mathrm{kg})(10500 \,\mathrm{m/s})}{2(274 \,\mathrm{kg})} $$ Finally, compute the speed of the satellite after the collision: $$ v_{f, 1} \approx 22350 \,\mathrm{m/s} $$ Hence, the speed of the satellite after the collision is approximately \(22350 \,\mathrm{m/s}\).

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Key Concepts

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

Conservation of Linear Momentum
The concept of conservation of linear momentum is essential in understanding physical interactions where no external forces act on the system. According to this principle, the total linear momentum of a system remains constant if it is not influenced by external forces.

When a satellite slingshot maneuver occurs, it is an excellent example of this conservation law in action. The satellite and the planet form an isolated system where, for a brief moment, their mutual gravitational forces are the only significant interactions. During this time, the total linear momentum before and after the encounter must be the same.

Mathematically, this is expressed as: \[ m_1v_{i, 1} + m_2v_{i, 2} = m_1v_{f, 1} + m_2v_{f, 2} \] where \(m_1\) and \(m_2\) are the masses, and \(v_{i, 1}\), \(v_{i, 2}\), \(v_{f, 1}\), and \(v_{f, 2}\) are the initial and final velocities of the satellite and the planet, respectively.

In our exercise, by recognizing that the planet’s mass is much greater than the satellite's mass, we simplify our calculations by assuming the planet's velocity does not significantly change, leading us to find the final velocity of the satellite post-interaction.
Conservation of Kinetic Energy
The conservation of kinetic energy is another fundamental principle, which states that in an isolated system with no non-conservative forces (like friction or air resistance), the total kinetic energy remains constant during an elastic collision.

An elastic collision is one in which both momentum and kinetic energy are conserved. This assumption is crucial in the satellite slingshot effect since it allows the satellite to gain speed without any external energy input, simply by interacting with a moving planet.

The formula that expresses this conservation is: \[ \frac{1}{2} m_1v_{i, 1}^2 + \frac{1}{2} m_2v_{i, 2}^2 = \frac{1}{2} m_1v_{f, 1}^2 + \frac{1}{2} m_2v_{f, 2}^2 \] This is fundamental in our problem for determining the satellite's final speed, as we equate the initial total kinetic energy with the final total kinetic energy to obtain the necessary equations for solving.
Elastic Collision
An elastic collision is particularly significant when talking about satellite maneuvers, like the slingshot effect. In an elastic collision, two bodies bounce off each other without losing kinetic energy to other forms, like heat or sound.

During a satellite's slingshot maneuver around a planet, it can be modeled as an elastic collision because the gravitational interaction does not generate significant heat or other energy losses; instead, the satellite's path is just redirected, and its speed is changed.

Understanding elastic collisions enables scientists and engineers to predict the outcomes of such maneuvers accurately, ensuring the satellite achieves the required velocity to reach its destination. The assumption of an elastic collision simplifies our equations and allows us to solve for the satellite’s final velocity post-collision.
Final Velocity Calculation
The final velocity calculation of the satellite after the slingshot effect combines the conservation principles discussed above. By setting up equations for the conservation of linear momentum and kinetic energy and assuming an elastic collision, we can solve for the satellite's final velocity.

In our exercise, we derived a simplified expression for the final speed of the satellite: \[ v_{f, 1} = \frac{(2m_1+m_2)v_{i, 1} - m_2v_{i, 2}}{2m_1} \] After inserting the values, we can calculate the final velocity that the satellite will have after the slingshot maneuver.

This step is crucial for space missions, as it determines how the satellite will benefit from the slingshot effect to reach farther destinations with less fuel consumption. The calculations are complex but essential for mission success.

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Most popular questions from this chapter

After several large firecrackers have been inserted into its holes, a bowling ball is projected into the air using a homemade launcher and explodes in midair. During the launch, the 7.00 -kg ball is shot into the air with an initial speed of \(10.0 \mathrm{~m} / \mathrm{s}\) at a \(40.0^{\circ}\) angle; it explodes at the peak of its trajectory, breaking into three pieces of equal mass. One piece travels straight up with a speed of \(3.00 \mathrm{~m} / \mathrm{s}\). Another piece travels straight back with a speed of \(2.00 \mathrm{~m} / \mathrm{s}\). What is the velocity of the third piece (speed and direction)?

The nucleus of radioactive thorium- 228 , with a mass of about \(3.8 \cdot 10^{-25} \mathrm{~kg}\), is known to decay by emitting an alpha particle with a mass of about \(6.68 \cdot 10^{-27} \mathrm{~kg} .\) If the alpha particle is emitted with a speed of \(1.8 \cdot 10^{7} \mathrm{~m} / \mathrm{s},\) what is the recoil speed of the remaining nucleus (which is the nucleus of a radon atom)?

One of the events in the Scottish Highland Games is the sheaf toss, in which a \(9.09-\mathrm{kg}\) bag of hay is tossed straight up into the air using a pitchfork. During one throw, the sheaf is launched straight up with an initial speed of \(2.7 \mathrm{~m} / \mathrm{s}\). a) What is the impulse exerted on the sheaf by gravity during the upward motion of the sheaf (from launch to maximum height)? b) Neglecting air resistance, what is the impulse exerted by gravity on the sheaf during its downward motion (from maximum height until it hits the ground)? c) Using the total impulse produced by gravity, determine how long the sheaf is airborne.

A 60.0 -kg astronaut inside a 7.00 -m-long space capsule of mass \(500 . \mathrm{kg}\) is floating weightlessly on one end of the capsule. He kicks off the wall at a velocity of \(3.50 \mathrm{~m} / \mathrm{s}\) toward the other end of the capsule. How long does it take the astronaut to reach the far wall?

A bored boy shoots a soft pellet from an air gun at a piece of cheese with mass \(0.25 \mathrm{~kg}\) that sits, keeping cool for dinner guests, on a block of ice. On one particular shot, his 1.2-g pellet gets stuck in the cheese, causing it to slide \(25 \mathrm{~cm}\) before coming to a stop. According to the package the gun came in, the muzzle velocity is \(65 \mathrm{~m} / \mathrm{s}\). What is the coefficient of friction between the cheese and the ice?
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