Introduction: Free-body diagrams and friction

Physics 1A03 Team

Introduction: Free-body diagrams and friction

The basis of what we cover in 1A03 has been understood for hundreds of years. These fundamental laws of physics, while not new, are still highly relevant and applicable. Through the discovery of new and exciting daily applications, we further our understanding of the world around us. While this particular lab focuses on the groundbreaking work of Sir Isaac Newton, it’s important to acknowledge that our current understanding of physics is a result of the combined efforts of large diverse groups of scientists. By performing these labs, you are gearing up to contribute to the vast data and understanding of our universe, and you are training to become scientists (fight imposter syndrome!). A big part of the understanding process has been developing tools like mathematical notation and free-body diagrams. In this lab you will use these tools to understand the forces in your experiments.

Pictorial representations of the three laws of motion. 1. If F = 0, a = 0, top: Physics Girl on a skateboard travelling at a constant velocity, bottom: a fan blows causing an unbalance force and Physics Girl now accelerates on her skateboard. 2. F = ma, top: Physics Girl pushes on a small box with force F causing a large acceleration, bottom: Physics Girl pushes on a large box with the same force F, causing a small acceleration. 3. Action-reaction. Forces come in pairs, each part of the pair acts on one of the objects. Top: Physics Girl and her twin both pull on a rope, and each experience a force F, bottom: the rope is now attached to a wall, Physics Girl pulls with a force F, and is pulled by the rope with a force F. — Pictorial representations of the three laws of motion. 1. If there is no net force there will be no acceleration (an object in motion tends to stay in motion, an object at rest tends to stay at rest). 2. Net force = mass x acceleration, for the same force a lighter object will experience a larger acceleration. 3. Action-reaction: forces come in pairs for every action there is an equal and opposite reaction. These force pairs act on different objects. In magnitude F_{A on B} = F_{B on A}.

In Exercise 1, you will use free-body diagrams to predict the results of the upcoming experiments. By using the free-body diagram as a tool, you will see how the forces in Exercises 1-4 should balance. Additionally, you will develop equations of motion that you will test in the following exercises.

In Exercise 2, you will measure the force of static friction between your shoe and an inclined smooth surface. By measuring the angle of the inclined surface where the shoe just begins to slip, you will be able to quantify the coefficient of static friction between your shoe and the flat surface (i.e. measure the mu of a shoe).

In Exercise 3, you will measure another friction coefficient, but this time you will be looking at kinetic friction. Similar to Exercise 2, you will put your shoe on an inclined surface. In this exercise, the shoe will accelerate down the ramp, and you can determine this acceleration by taking two measurements: the length of the ramp and the time it takes to slide down the ramp. Once you know the acceleration of your shoe, you can calculate the coefficient of kinetic friction.

In Exercise 4, you will interpret and draw a graph of the frictional force as a function of the applied force. This will lead into a final discussion question in Exercise 5 that will test your understanding of all these concepts.

Learning Objectives

Set yourself the following learning outcomes for this lab:

By the end of this lab, I will

Analyze physical situations, and draw representative free-body diagrams for both stationary and in-motion scenarios.
Develop equations that describe both the force of static friction and kinetic friction.
Apply the concepts of friction to real-life scenarios that exemplify acceleration, static forces, and dynamic forces.
Identify static versus kinetic frictional forces and how they affect motion.

But before any of that, it’s important to get warmed up!

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Physics 1A03 - Laboratory Experiments Copyright © by Physics 1A03 Team is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License, except where otherwise noted.

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