Goal: To understand Newton’s 2 nd law and its applications to motions. Objectives: 1)To learn about how accelerations work 2)To understand Newton’s Force.

Slides:

Advertisements

Similar presentations

Stop Faking It! Force & Motion.

Advertisements

Newton’s 1st Law of Motion

The Nature of Force Chapter 10 section 1.

Forces and Newton’s Laws NOTES

Newton’s 2nd Law of Motion F=ma. units Multiple forces can be exerted on an object at the same time.

What is Newton’s Third Law

Newton’s Laws of Motion

 Calculate the acceleration that this object experiences 30 kg 150 N.

Newton’s Second and Third Laws

Physics the study of the relationship between matter and energy.

Module 4, Recitation 1 Concept Problems, Newton’s three laws.

Do Now Monday, 4/2 Take our your notebook and answer the following question: What is the difference between weight and mass? You have 4 minutes. I will.

Forces. Newton’s First and Second Laws Newton’s 1 st law of motion deals with inertia An object at rest remains at rest, an object in motion maintains.

Newton’s 2 nd Law. Force on Object Objects acted on by a net unbalanced force will accelerate in the direction of the force This means they will speed.

Chapter 3 Lesson 2.

P2 – Forces and Motion Lesson 4: Forces 1.

Chapter 3 Forces.

Goal: To understand Newton’s 2 nd law. Objectives: 1)To understand Newton’s Force Law 2)To learn about how Weight works 3)To learn about the basics of.

The Laws of Motion Chapter 4.

Jeopardy Newton’s 1 st Law Newton’s 2 nd Law Newton’s 3 rd Law Momentum Everything Else Q $100 Q $200 Q $300 Q $400 Q $500 Q $100 Q $200 Q $300 Q $400.

Do Now: What are Newton’s 3 Laws of Motion?. Do Now: What are Newton’s 3 Laws of Motion?

Newton’s 2 nd & 3 rd Laws. A couple things to keep straight Mass = the amount of “stuff” something is made of. Weight = the measure of the force of gravity.

Newton’s Three Laws Forces and Motion. What Is a Force? Any influence that may change the motion of an object For example: a push, a pull, an attraction,

CHAPTER 2 p. 36 m Section 1 the nature of force.  Force: is a push or a pull.  When an object pushes or pulls on another object then you say the 1 st.

12/12Newton’s 1 st law/inertia In each of the following situations, determine of the object will be at rest, speeding up, slowing down or going at a constant.

Newton’s Laws of Motion 1 st - Inertia. 2 nd - F = ma 3 rd - Action/Reaction Take notes when see.

The Nature of Force Chapter 3 section 4 What is a force Force is a push or pull. Forces are either balanced or unbalanced.

Conceptual Example 4-4: What exerts the force to move a car?

Newton’s Second Law: Force, Mass, and Acceleration Sections

Chapter 4 9/20/2012. Newton’s 2 nd Law ~ Newton’s 2 nd law of motion says that a net force acting on an object causes the object to accelerate in the.

Laws of Motion Forces: chapter st Law An object at rest remains at rest and an object in motion maintains its velocity unless it experiences an.

Vocab (5.5, 5.9) April 10 th, 2007: 1. Weight: F w ; the amount of gravitational force that the earth exerts on an object 2. Acceleration due to gravity:

Forces and Motion. Contents Velocity and Acceleration Velocity and Acceleration D-T Graph D-T Graph S-T Graph S-T Graph Newton’s Laws of Motion Newton’s.

Goal: To understand Newton’s 3 rd law. Objectives: 1)To understand how actions create Opposite reactions 2)To examine Applications to this law 3)To learn.

Newton’s Second and Third Laws Chapter 4 Section 3.

Chapter 6 Forces in Motion.

Chapter 12: Forces and Motion Objectives: 1.Define forces and explain how they affect an object’s motion 2.Relate Newton’s laws to real life circumstances.

Newton’s 3 rd Law of Motion Chapter 6 Section 4 Wednesday, December 23, 2015Wednesday, December 23, 2015Wednesday, December 23, 2015Wednesday, December.

Force and Motion ISCI Force: ‘push’ or ‘pull’ on an object 2. Objects in motion stay in motion unless enacted upon by a ‘unbalanced’ force. Newton’s.

Chapter 3 Force, Mass and Acceleration Newton’s Laws.

FORCES AND NEWTON’S LAWS OF MOTION. FORCES In order to make an object at rest move, you need to apply a push or a pull, otherwise known as a force. A.

Goal: To understand angular motions Objectives: 1)To learn about Circular Motions 2)To learn about Rotational Inertia 3)To learn about Torque 4)To examine.

1 Forces Laws of Motion. 2 Newton’s First Law of Motion An object at rest remains at rest and an object in motion maintains its velocity unless it experiences.

FORCES Test on Wednesday speed DvT Acceleration Forces.

Chapter 4 1 ZAP !

Chapter 6 and 7. momentum = mass x velocity p = mv units: kgm/s or Ns.

Chapter 3 Forces. Section 1 Newton’s Second Law Force, Mass and Acceleration Compare hard thrown ball vs. gently tossed ball Compare hard thrown ball.

Section 2Forces Section 2: Gravity Preview Key Ideas Bellringer Weight and Mass Law of Universal Gravitation Free Fall Projectile Motion.

A. Newton’s Laws Sir Isaac Newton (1642–1727)  able to state rules that describe the effects of forces on the motion of objects I. The First 2 Laws of.

What holds us together? Gravity. Gravity is a force Force: a push or pull exerted on an object Gravity: the attractive force between objects; force that.

Crash Course in Motion PS-5.3, 5.4, 5.5, 5.9, and 5.10.

12.3 Newton’s Third Law of Motion and Momentum 4. A 25-N force accelerates a boy in a wheelchair at 0.5 m/s2. What is the mass of the boy and the wheelchair?

Physical Science Chapter 12 Force. Ball demos Ball on table Rolling.

Goal: To understand Newton’s 2nd law.

Goal: To understand Newton’s 2nd law and its applications to motions.

Newton’s Second Law of Motion

FORCE A force is any influence that can change the velocity of a body. Forces can act either through the physical contact of two objects (contact forces:

Force is part of an interaction

Newton’s Second Law F = ma.

Force equals mass times acceleration.

Notes 2.2: Newton’s 2nd Law of Motion

FORCE and MOTION REVIEW

Object at rest stays at rest,

Object at rest stays at rest,

Momentum and Impulse SPH4U.

Gravity and Freefall.

Newton’s 2nd Law of Motion

Newton’s 1st and 2nd Laws.

Gravity and Freefall.

Force - a push or pull on an object

Presentation transcript:

Goal: To understand Newton’s 2 nd law and its applications to motions. Objectives: 1)To learn about how accelerations work 2)To understand Newton’s Force Law 3)To learn how accelerations change velocities 4)To apply this to position and motion charts

Breakdown Distance = change in position can be either a scalar or a vector Velocity = rate of change of position Velocity = change in distance / change in time Velocity is always a VECTOR (speed is the scalar) Acceleration = the rate of change of velocity Acceleration = change in velocity / change in time Since velocity is a vector and acceleration depends on velocity therefore acceleration is always a VECTOR NOTE: change = final - initial

Units Distance: meters (m) and sometimes meters direction Velocity: m/s direction Acceleration: m/s 2 direction

Law 2: Force Law Force = mass * acceleration Force is how much you are pushing or pulling on something Mass is how much stuff you have (NOTE: mass is NOT weight!!!) Acceleration is the rate at which you change your velocity. Net force = mass * net acceleration

Example Force of gravity I have a mass of 90 kg. What is my force of gravity F = ma Here a = g So, F = mg NOTE: force of gravity is NOT 9.8!

Demo time! I will attempt to walk off the skateboard To do this I will exert a force on the skateboard and a force will push me forward (this is Newton’s 3 rd law but we will look at that more later. So, both I and the skateboard will get a force and it will be the same force. The question is, what will happen to the skateboard?

Acceleration Acceleration = net force / mass So, with equal forces, the smaller the mass, the bigger the acceleration. Half the mass means double the acceleration.

But Um but doesn’t gravity pulls everything at the same acceleration? Yes! So, what does that tell you about the force of gravity?

Follow up An astronaut is in orbit around the earth. The mass of the astronaut is 100 kg and the mass of his spaceship is 5000 kg. What are the “weights” of the astronaut and spacecraft (hint what is the net force on them?)? Suppose the astronaut applies a 1000 N force on the spacecraft. What will the acceleration of the spacecraft be? If the same force were applied to the astronaut, what would the acceleration of the astronaut be? Why are the two accelerations so different?

Net force vs acceleration The net acceleration depends on net force. However, an object in motion will remain in motion until the acceleration can stop it. For example, if a car is moving forward and you hit the breaks the breaks will create an acceleration backwards. This will stop the car but not for a few seconds.

Example A car is moving forward at 20 m/s forward. A force of 4 m/s 2 backwards is applied. How long does it take for the car to stop?

Thrown ball Acceleration has direction. Imagine I throw a ball horizontally. What will the acceleration in the horizontal direction be?

Two balls I will drop one and throw the other horizontally. Which one will hit the ground first?

Conclusion We have seen from Newton’s 2 nd law that force = mass * acceleration Your acceleration depends on your mass – smaller masses have bigger accelerations with the same force. If you are in freefall you have no weight but still have gravity If you are not in freefall then your net acceleration depends on your net force. We have examined how accelerations affect velocities