Reciprocity: Difference between revisions

From Physics Book
Jump to navigation Jump to search
Line 21: Line 21:


===A Mathematical Model===
===A Mathematical Model===
 
The force due to gravity is:
'''Gravitational Force Equation:'''
::*<math>|\vec{\mathbf{F_g}}|=\frac{Gm_{1}m_{2}}{r^2}</math>
 
[[File:gravity_equation_new.jpg]]


Although the force of gravity is dependent on mass, both experience the same magnitude of gravitational force.
Although the force of gravity is dependent on mass, both experience the same magnitude of gravitational force.

Revision as of 15:42, 14 June 2019

claimed by Nicole Romer (Spring 2017)

edited by Laurentino Castro (Spring 2018)

This section covers the top of reciprocity while also explaining why forces, such as gravitational and electric forces, act on each other with equal magnitudes.

This is an example of reciprocity. The book is exerting a contact force on the table and the table is exerting a contact force on the book.

The Main Idea

Reciprocity is the idea that the force object 1 exerts on object 2 is the same as the force object 2 exerts on object 1. This idea comes from Newton's Third Law of Motion, which states that every action has an equal and opposite reaction. For example, if I put my hand on a table, I am exerting a contact force on the table. Because my hand doesn't go straight through the table but instead rests on top of it, the table must also be exerting a force on me that is equivalent to the force I am placing upon it. Though it seems like I am putting in more effort, the forces are the same.

Newton's 3rd law implies that all forces come in pairs. The two forces are called "action" and "reaction" pairs. When forces are in these pairs, the magnitude of the two forces equal each other. However, in vector form, the two forces would be in opposite directions of each other, so one force would have a negative sign on it. This applies to both the gravitational and electric forces. Contact forces that we observe (such as the normal force) are actually due to electrical forces at the atomic level.

Because these forces are equal, so are the changes in momentum of the objects the forces are acting upon (remember, [math]\displaystyle{ |\vec{\mathbf{F}}|=|\frac{d\vec{\mathbf{p}}}{dt}| }[/math]). Two planets exerting attractive forces on each other will have the same change in momentum over the same amount of time. However if one planet is much larger it will have a much smaller change in velocity then the smaller planet. This is because p = mv and thus [math]\displaystyle{ {\Delta}v={\Delta}p/m }[/math]. So even though the forces will be the same, they may appear unequal due to a smaller change in velocity in a larger object.

The following image showcases the principle of reciprocity as the two people pulling exert an equal and opposite force on each other through tension. Also the object laying motionless on a surface has a net force of zero because the normal force of the table is equal to that of gravity on the object.

A Mathematical Model

The force due to gravity is:

  • [math]\displaystyle{ |\vec{\mathbf{F_g}}|=\frac{Gm_{1}m_{2}}{r^2} }[/math]

Although the force of gravity is dependent on mass, both experience the same magnitude of gravitational force.

Electric Force: F_elec=k(q1*q2)/r^2

Electric forces will attract each other with the same magnitude of force, but the reciprocity rule also applies to two repelling forces as they are pushed away with the same magnitude. These scenarios are shown in the image above.

Formulaic representation of reciprocity:

F1on2=-F2on1.

The vector form of reciprocity is this:

<F,0,0> is one force.

<-F,0,0> is the exact same force but in the opposite direction.


This is the equation in vector format. When the vector of one force is in one direction. Usually, the vector is in the other direction

This equation on the left side. shows that object one is acting on object 2. The equation on the right side shows the reverse.

Examples

Be sure to show all steps in your solution and include diagrams whenever possible

Simple

If you exert 20 N on the table, what would be the normal force of the table on you?

Since you are exerting 20 Newtons, due to reciprocity the table will be exerting a normal force of 20 Newtons.


If push a box with a force of 15 N, what is the reciprocal force of the box on you?

The box exerts a force of 15 N on you, in the opposite direction of your force on the box.

Middling

A 60 kilogram man stands on the surface of the Earth. What is the force Earth exerts on the man? What is the force the man exerts on the Earth?

60x9.8=588N. Due to reciprocity 588 is the force on both Earth and the man.


A box is sitting on Earth's surface. The Earth exerts a force of 196 N on the box. What is the force on the Earth? How much does the box weigh?

196N/9.8 = 20 kg. Due to reciprocity, the box exerts 196N of force on the earth.

Difficult

This problem is from our test.

Two blocks of mass m1(under rod) and m3(above rod) are connected by a rod of mass m2. A constant unknown force F pulls upward on the top block while both blocks and the rod move upward at a constant velocity v near the surface of the Earth. The direction of the gravitational force on each block points down. Find F1on2, the force exerted by the bottom block on the rod.

Fnet1=0 due to constant v

F2on1-m1gy=0

F2on1=m1gy

F1on2=-m1gy


You are pulling a rope with a force of 15 N. The rope is connected to a box on a frictionless surface. The rope and box are moving at a constant rate. Find the force of the rope of the block, the block on the rope, and the rope on you.

Fnet = 0 (because constant velocity)

The Force of the rope on you is -15 N (reciprocity)

The Force of the rope on the box is 15 N

The Force of the box on the rope is -15 N

Connectedness

  1. The first physics I ever learned was Newtons laws. Before heading into any science class, I always thought, every reaction gets an equal and opposite reaction. I didnt really understand it. That is a fundamental principle that we use in almost all physics problems. It has been test questions and homework questions. The thing that intrigues me the most is how an ant can be pushing against a rhino and though the rhino is so much bigger, they are still exerting the same force.
  2. I am an industrial engineering major and though there is very minimal use of physics in that field, I do believe it is something that will help us go about our days knowing that force isn't how much effort you put in but about the action reaction pairs.
  3. Forces are something we deal with everyday. Everything we touch, me typing this page right now is all the result of forces. An important industry that deals with this is the automobile industry. If we understand the forces of the wheels on the road, we will know how to make wheels that best suit an automobile.
  4. This topics is one of the fundamental underlying principles of physics. It applies to pretty much everything in physics.
  5. Physics applies to almost any major. As an Environmental Engineer reciprocity is important to remember reciprocity, specifically in waste water management. Water pressure (force from water on pipe and force from pipe on water) is important when designing water infrastructure.
  6. Reciprocity is important to remember in buildings. When creating a structure that can sustain a storm, you have to think about how high winds will change how parts of the structure interact with each other.
  7. I remember back in elementary school the example that my teacher used was: when you kick a can, which experiences a greater force, the can or your foot? I was astonished to find out that both experienced a equal force due to reciprocity. I spent weeks kicking cans trying to understand this phenomenon until I learned for myself the forces were experienced relative to mass. This was my first real exposure to seeking to understand the world through the lens of physics.

History

Isaac Newton was born in Woolsthorpe, England. When he was a child, one day he was resting under an apple tree when suddenly an apple fell on his head. He thought about why things fall down and not fall back up. He spent years figuring out the phenomenon. After all this, he came up with three laws of motion. This is when he discovered gravitation as a force. Where Newton's Law comes into play is that the Earth is exerting a force on us to stay with it since closer objects exert stronger forces on each other. We are also exerting a force on Earth so that we stay on the ground and don't go flying off. The date of this story is not known, and some even believe it to be a myth. However William Stukeley, author of Memoirs of Sir Isaac Newton's Life noted that he had a conversation with Newton and Newton talked about why an apple falls to the ground due to gravitational interaction.

See also

Further reading

1:http://www.physicsclassroom.com/class/newtlaws/Lesson-4/Newton-s-Third-Law
2:Matter and Interactions By Ruth W. Chabay, Bruce A. Sherwood - Chapter 3.4

External links

https://www.youtube.com/watch?v=NfuKfbpkIrQ

References

1: http://www.mainlesson.com/display.php?author=baldwin&book=thirty&story=newton
2: https://www.newscientist.com/blogs/culturelab/2010/01/newtons-apple-the-real-story.html
3: http://www.physicsclassroom.com/class/newtlaws/Lesson-4/Newton-s-Third-Law
4: http://www.schoolphysics.co.uk/age16-19/Mechanics/Statics/text/Vectors_in_equilibrium/index.html
5: Matter and Interactions By Ruth W. Chabay, Bruce A. Sherwood - Chapter 3.4