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Chapter 3: Problem 51

A professional golfer can hit a ball with a speed of 70.0 \(\mathrm{m} / \mathrm{s}\) . What is the maximum distance a golf ball hit with this speed could travel on Mars, where the value of \(g\) is 3.71 \(\mathrm{m} / \mathrm{s}^{2}\) ? (The distances golf balls travel on earth are greatly shortened by air resistance and spin, as well as by the stronger force of gravity.)

Short Answer

Expert verified
Approximately 1320.75 meters.

Step by step solution

01

Understand the Problem

To solve for the maximum distance a golf ball can travel, we analyze the motion as a projectile. The initial speed is given as 70.0 m/s and the acceleration due to gravity on Mars is 3.71 m/s². We need to find the maximum horizontal distance for given initial conditions.
02

Apply Projectile Motion Formula

When launched at an angle of 45° (optimal angle for maximum distance), projectile motion is symmetrical and happens as highest range. Using the formula for range \[R = \frac{v^2 \sin(2\theta)}{g}\], where \(v = 70.0 \, \text{m/s}, \theta = 45°\), \(g = 3.71 \, \text{m/s}^2\).
03

Calculate the Sine of Double the Angle

The angle \(\theta\) is 45°, hence \[\sin(2\theta) = \sin(90°) = 1\].
04

Solve for Maximum Distance on Mars

Substitute the values into the range formula:\[R = \frac{(70.0)^2 \times 1}{3.71}\]. Simplifying, calculate:\[R = \frac{4900}{3.71} \approx 1320.75 \, \text{m}\].
05

Interpret the Result

The calculated range of approximately 1320.75 meters is the maximum distance a golf ball can travel on Mars given the conditions.

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Key Concepts

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

Mars gravity
Gravity on Mars is considerably weaker compared to Earth. While Earth's gravity is approximately 9.81 m/s², Mars exhibits a gravitational acceleration of merely 3.71 m/s². This implies that objects in free-fall on Mars experience a much lesser force pulling them down.
For projectiles, this reduced gravity means they can travel farther horizontally given the same initial speed. This is because the downward pull is weaker, allowing the projectile more time in the air. As a result, the maximum distance a projectile can travel becomes significantly greater.
Understanding Mars gravity is essential when solving projectile problems as it directly influences both the motion path and the range of the projectile.
Optimal launch angle
One of the crucial factors in maximizing the range of a projectile is the launch angle. Intuitively, we might think that a steeper angle would launch a projectile further, but there is a specific angle that achieves the maximum distance.
In the absence of air resistance, the optimal launch angle for maximum range is 45 degrees. At this angle, the projectile's motion is effectively balanced between vertical height and horizontal distance. The launch angle influences the time the projectile remains in the air and the initial speed distribution in vertical and horizontal components.
On planets like Mars, the optimal angle remains 45 degrees because the force of gravity still acts downwards uniformly, and air resistance is negligible in this consideration.
Range formula
The range formula is vital for determining how far a projectile will travel when launched. The formula is given by:\[ R = \frac{v^2 \sin(2\theta)}{g} \]where:
  • \( R \) is the range or maximum horizontal distance
  • \( v \) represents initial velocity
  • \( \theta \) is the launch angle
  • \( g \) is the acceleration due to gravity
This formula considers both the initial speed and the angle in conjunction with gravitational force.
Inserting the recognized optimal launch angle of 45 degrees simplifies the formula since \( \sin(90°) = 1 \). This is what makes calculations for maximum range simpler, particularly in an environment like Mars where gravity is reduced.
Physics problem solving
Solving physics problems, particularly involving projectile motion, requires a comprehensive understanding of underlying principles and systematic approaches. Here's a step-by-step guide to solving such problems:
  • **Understand the problem:** Analyze what is given and what is required. Ensure all units are consistent.
  • **Identify key components:** Recognize initial velocity, angle of launch, and gravitational force.
  • **Apply suitable formulas:** Depending on what needs to be solved (e.g. distance, time, height), choose the relevant equations.
  • **Make calculations:** Insert known values into formulas and compute results.
  • **Interpret results:** Make sense of your findings in the context of the problem.
A systematic approach not only aids in getting to the correct solution but also helps in deeply understanding physical concepts involved. This method is crucial when solving problems on different planetary environments like Mars.

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Most popular questions from this chapter

Fighting forest fires. When fighting forest fires, airplanes work in support of ground crews by dropping water on the fires. A pilot is practicing by dropping a canister of red dye, hoping to hit a target on the ground below. If the plane is flying in a horizontal path 90.0 \(\mathrm{m}\) above the ground and with a speed of \(64.0 \mathrm{m} / \mathrm{s}(143 \mathrm{mi} / \mathrm{h}),\) at what horizontal distance from the target should the pilot release the canister? Ignore air resistance.

\cdotse: Leaping the river, II. A physics professor did daredevil stunts in his spare time. His last stunt was an attempt to jump across a river on a motorcycle. (See Figure \(3.45 .\) ) The takeoff ramp was inclined at \(53.0^{\circ},\) the river was 40.0 \(\mathrm{m}\) wide, and the far bank was 15.0 \(\mathrm{m}\) lower than the top of the ramp. The river itself was 100 \(\mathrm{m}\) below the ramp. You can ignore air resistance. (a) What should his speed have been at the top of the ramp for him to have just made it to the edge of the far bank? (b) If his speed was only half the value found in \((a)\) where did he land?

\(\bullet\) Two archers shoot arrows in the same direction from the same place with the same initial speeds but at different angles. One shoots at \(45^{\circ}\) above the horizontal, while the other shoots at \(60.0^{\circ} .\) If the arrow launched at \(45^{\circ}\) lands 225 \(\mathrm{m}\) from the archer, how far apart are the two arrows when they land? (You can assume that the arrows start at essentially ground level.)

. A man stands on the roof of a 15.0 -m-tall building and throws a rock with a velocity of magnitude 30.0 \(\mathrm{m} / \mathrm{s}\) at an angle of \(33.0^{\circ}\) above the horizontal. You can ignore air resistance. Calculate (a) the maximum height above the roof reached by the rock, (b) the magnitude of the velocity of the rock just before it strikes the ground, and (c) the horizontal distance from the base of the building to the point where the rock strikes the ground.

You're standing outside on a windless day when raindrops begin to fall straight down. You run for shelter at a speed of \(5.0 \mathrm{m} / \mathrm{s},\) and you notice while you're running that the raindrops appear to be falling at an angle of about \(30^{\circ}\) from the vertical. What's the vertical speed of the raindrops?
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