Momentum Principle

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This page discusses the Momentum Principle and examples of how it is used.

Claimed by Niveda Shanmugam for Spring 2018

The Main Idea

The Momentum Principle is a fundamental principle of mechanics and will be used in almost all further problems you will encounter in Physics! As we know, momentum is given by the product of mass and velocity and is consequently directly proportional to the magnitude of the mass and velocity of any particular object.

The Momentum Principle, also known as the Momentum Conservation Principle, essentially states that for a collision occurring between object 1 and object 2 in an isolated system, the total momentum of the two objects before the collision is equal to the total momentum of the two objects after the collision. This makes sense as it restates Newton's first law ( An object at rest stays at rest and an object in motion stays in motion with the same speed and in the same direction unless acted upon by an unbalanced force). The key word here is "isolated" - when an external force affects the system, momentum can be changed. Overall, the momentum principle assumes that the final momentum is dependent on the initial momentum, the force applied, and the duration in which the force is applied.

A Mathematical Model

The Momentum Principle is defined as [math]\displaystyle{ {\frac{d\vec{p}}{dt}}_{system}= \vec{F}_{net} }[/math] (or [math]\displaystyle{ ∆\vec{p} = \vec{F}_{net} * {∆t} }[/math]). As a result, the momentum principle can alternatively be written as [math]\displaystyle{ \vec{p}_{f}=\vec{p}_{i}+\vec{F}_{net}* {∆t} }[/math].

[math]\displaystyle{ \vec{p} }[/math] is the momentum of the system. In the equation, impulse (measured in [math]\displaystyle{ kg*{\frac{m}{s}} }[/math] ) is expressed as the "change in momentum" ([math]\displaystyle{ ∆\vec{p} = \vec{p}_{final} - \vec{p}_{initial} }[/math]), which includes both the magnitude and direction of the momentum. Therefore, momentum is a vector quantity.


[math]\displaystyle{ \vec{F}_{net} }[/math] is the net force from the surroundings. Force (measured in Newtons, or N) includes the interactions between the system and the surroundings, like the gravitational force exerted by the Earth on us or the force that a compressed spring exerts on a mass. Because momentum is defined as a vector, in the Momentum Principle, the force includes both the magnitude and direction. Also, it is important to note that the Momentum Principle calls for the net force, which is the sum of all the different forces from the surroundings. This becomes essential when an object has multiple forces acting on it like the force of gravity, the force of a spring, force of friction, etc. as all of these, keeping in mind their respective directions, have to be added to get the net Force.

To avoid errors, here is a systematic procedure to follow when approaching problems involving this concept:

Step 1: Define system and surroundings.

Step 2: Draw a free body diagram - This is a helpful way to determine the various forces acting on the system.

Step 3: Use the Momentum Principle to calculate the value needed.

An Example

Click on the picture to read a description!

In this example, the ball is not moving, meaning it has a velocity of zero. If the velocity is zero, there is no change in momentum, meaning that net force is also zero. Therefore, we can conclude that initial and final momentum are equal due to the ball not moving. Therefore, [math]\displaystyle{ ∆\vec{p}=0 }[/math], and thus [math]\displaystyle{ \vec{F}_{net} = 0 }[/math]. Because the net force is equal to zero, this means that the force due to tension is equal in magnitude and opposite in direction to the force due to gravity.

[math]\displaystyle{ t }[/math] is the time (measured in seconds, or s). Specifically, the Momentum Principle calls for the "change in time" ([math]\displaystyle{ ∆\vec{t} = \vec{t}_{final} - \vec{t}_{initial} }[/math]), or in other words, the duration of the interaction is needed. Overall, if a force is applied to a system over a greater duration, the change in momentum is greater, as the momentum principle, [math]\displaystyle{ ∆\vec{p} = \vec{F}_{net} * {∆t} }[/math], also demonstrates that the change in momentum is directly proportional to the duration of the applied force.

Momentum Principle Continued

The Momentum Principle can be further manipulated to find the change in velocity of the system. This is represented by the formula: [math]\displaystyle{ \vec{v}_{f}=\vec{v}_{i}+{\frac{\vec{F}_{net}}{m}}*{∆t} }[/math].

[math]\displaystyle{ \vec{v}_{f} }[/math] is the final velocity of the system, and [math]\displaystyle{ \vec{v}_{i} }[/math] is the initial velocity of the system. The difference between the two can be shortened to [math]\displaystyle{ \vec{{∆v}} }[/math], and represents the change in velocity of the system.

[math]\displaystyle{ \vec{F}_{net} }[/math] is the net force acting on the system.

[math]\displaystyle{ m }[/math] is the mass of the system.

[math]\displaystyle{ {∆t} }[/math] is the change in time of the system in which it is acted on by the force.

This manipulation of the momentum principle is very useful when it comes to updating the position of the system because it gives you the change in velocity over the observed time interval.

Previous Example Continued

Click on the link to see the Momentum Principle through VPython!

Make sure to press "Run" to see the principle in action!

[1]

Here, we see the same ball and spring model from before, except we see the spring oscillating! This is because we start with a momentum (velocity greater than 0) and as the spring and ball move, we update net force. From each new net force, we have a new momentum. This new momentum gives us a new velocity, that we can then add to the ball's previous position to update its location.

This is depicted in this code:

We will now continue to add arrows depicting gravitational force, spring force, net force, and momentum to gain a better understanding of how each change as the Momentum Principle continues.

Net Force is depicted by the RED arrow. Gravitation Force is depicted by the BLUE arrow, like before. Spring Force is depicted by the WHITE arrow, like before. Momentum arrow is depicted by the ORANGE arrow.

[2]

The differences in the code now just allow for arrows to represent each value. You can see these changes here:


Examples

Simple

Two external forces <40,-70,0>N and <20,10,0>N, act on a system. What is the net force acting on the system?

Answer: <60,-60,0>N

Explanation:

The net force is just synonymous for the overall force acting on the system. In this case, this is the sum of the forces given in the problem above.

[math]\displaystyle{ \vec{F}_{net} = \vec{F}_{1} + \vec{F}_{2} }[/math]

[math]\displaystyle{ \vec{F}_{net} }[/math] = <40,-70,0)N + <20,10,0>N = <60,-60,0>N

Middling

A hockey puck is sliding along the ice with nearly constant momentum <10,0,5>kg*m/s when it is suddenly struck by a hockey stick with a force <0,0,2000>N that lasts for only 3 milliseconds (3e-3s). What is the new (vector) momentum of the puck?

Answer: <10,0,11>kg*m/s

Explanation:

In this example, we are manipulating the momentum principle in order to calculate the new momentum at a given time. This is also called the update momentum formula.

[math]\displaystyle{ ∆\vec{p} = \vec{F}_{net} * {∆t} }[/math]

[math]\displaystyle{ \vec{p}_{final} - \vec{p}_{initial} }[/math] = [math]\displaystyle{ \vec{F}_{net} * {∆t} }[/math]

[math]\displaystyle{ \vec{p}_{final} }[/math] - <10,0,5>kg*m/s = <0,0,2000>N * (3e-3)s

[math]\displaystyle{ \vec{p}_{final} }[/math] = <10,0,11>kg*m/s


Difficult

In outer space a rock of mass 5kg is acted on by a constant net force <29,-15,40>N during a 4s time interval. At the end of this time interval the rock has a velocity of <114,94,112>m/s. What is the rock's velocity at the beginning of the time interval?

Answer: <90.8,106,80>m/s

Explanation:

This example is similar to the first example. Only now, instead of manipulating variables to solve for momentum, we must manipulate the variables to solve for velocity, specifically initial velocity. Velocity can be connected to the momentum principle since momentum is just mass multiplied by velocity.

[math]\displaystyle{ ∆\vec{p} = \vec{F}_{net} * {∆t} }[/math]

[math]\displaystyle{ \vec{p}_{final} - \vec{p}_{initial} = \vec{F}_{net} * {∆t} }[/math]

[math]\displaystyle{ \vec{p} = m * \vec{v} }[/math]

[math]\displaystyle{ m\vec{v}_{final} - m\vec{v}_{initial} = \vec{F}_{net} * {∆t} }[/math]

(5kg * <114,94,112>m/s) - (5kg * [math]\displaystyle{ \vec{v}_{initial} }[/math]) = <29,-15,40>N * 4s

[math]\displaystyle{ \vec{v}_{initial} }[/math] = <90.8,106,80>m/s

Connectedness

Why the Momentum Principle Connects to Your Interests

All over the world and at every point in time, interactions are continuously occurring, and I thought it was interesting to see how the Momentum Principle was the most fundamental principle that is used in starting to the analyze the different interactions. This fundamental idea allows us to examine how items collide, interact with each other, and most importantly, allow us to gain knowledge about how our everyday lives work as a whole.

How the Momentum Principle Connects to Your Major

Computer Science

While the momentum principle is often related to the tangible physical world, there are applications or tools when building software applications that apply to computer science. For example, if I was a software engineer trying to create Roller Coaster Tycoon, I would need to virtually calculate the correct and verifiable momentums for the roller coasters to mimic real world movements. This idea can even be expanded with relation to robotics where computer scientists aim to make hardware movement mimic human movement in the real world. Again, while not directly related, the concept of momentum and this fundamental idea must be learned and incorporated in order to benefit the future of technologies, especially with regard to the computer science realm.

Interesting Industrial Applications

While the Momentum Principle is not directly connected to the applications, it is often used in the process (especially in the beginning) of industrial application. For example, when creating life saving airbags and seat belts for cars, the Momentum Principle is used. The final momentum of a car during an accident would be zero, or would stop, and the initial momentum would be based on the mass and velocity of the car. With the change in momentum fixed, the airbag and seat belt would focus on increasing the time taken for the body's momentum to reach zero (final momentum), which would consequently reduce the force of the collision and protect the body from getting as injured. With the Momentum Principle being applicable in so many areas of my life, I found the concept even more interesting.

History

Although the Momentum Principle is credited as Newton’s second law of motion, it is difficult to just credit Isaac Newton (1643AD – 1727AD) for the development of the principle. As the Momentum Principle is the quantitative and more in-depth representation of Newton’s first law of motion (“An object tends to be at rest or moves in a straight line and a constant speed except to the extent that it interact with other objects”), the development of the first law also serves an important role in the history of the Momentum Principle. Aristotle (384BC – 322BC) initially proposed that objects had the natural tendency to be at rest and that a push (or a force) was absolutely needed to keep the object moving. His proposal was challenged by Galileo (1564AD – 1642AD), who introduced the idea that objects had the natural tendency to travel in a straight line at constant speed unless something (or a force) was interacting with something. Likewise, Descartes (1596AD – 1650AD) also contributed as he proposed three laws of nature in his “Principle of Philosophy,” which actually outlined the later published Newton’s first law of motion. After studying Descartes, Newton adopted Descartes’ principles as his first law of motion, and alongside the famous story of Newton sitting under an apple, Newton was able to create the Momentum Principle, or his second law of motion.

Why is this principle so important to us?

While we have known about the momentum principle for quite a long time now, many (including students) still wonder why the momentum principle is so important and crucial to learn. The reality of the matter is that this fundamental principle applies to many real world applications and can explain movement in the world of science. Whether its examining collisions between objects or impact breaking/building, the principle is a practical and useful way for us to explain how our real physical world works.

See also

As the Momentum Principle is the first of three fundamental principles of mechanics, the next possible topics to examine would be the other fundamental principles, the Energy Principle and the Angular Momentum Principle. Also, although the Momentum Principle is an extremely important concept that usually signals the start of a momentum related problem, the principle branches out into other momentum topics like Impulse and Iterative Prediction, which are used to solve other types of problems.

Further Reading

[1] http://espace.library.uq.edu.au/view/UQ:273253/Pap_290f_postprint.pdf

[2] http://authors.library.caltech.edu/2577/1/TOLpr30c.pdf

External links

[1] https://www.khanacademy.org/science/physics/linear-momentum/momentum-tutorial/v/introduction-to-momentum

[2] https://www.youtube.com/watch?v=ZvPrn3aBQG8

References

[1] Harris, William. "How Netwon's Laws of Motion Works." HowStuffWorks. HowStuffWorks.com, 29 July 2008. Web. 29 Nov. 2015. <http://science.howstuffworks.com/innovation/scientific-experiments/newton-law-of-motion.htm>

[2] Sherwood, Bruce A. "2.1 The Momentum Principle." Matter & Interactions. By Ruth W. Chabay. 4th ed. Vol. 1. N.p.: John Wiley & Sons, 2015. 45-50. Print. Modern Mechanics.

[3] Fenton, Flavio. "Momentum and Second Newton's Law." 26 Aug. 2015. Lecture.