Physics Demonstration Lab#6.6: The Impulse-Momentum and Work- Kinetic Energy Theorems For a Single Object on the Air Track

Similar documents
Momentum in One Dimension

Changes in Energy and Momentum

General Physics I Lab (PHYS-2011) Experiment MECH-3: Conservation of Momentum ]

Conservation of Momentum and Energy

Newton s Second Law. Newton s Second Law of Motion describes the results of a net (non-zero) force F acting on a body of mass m.

Activity P11: Collision Impulse and Momentum (Force Sensor, Motion Sensor)

Momentum & Energy Review Checklist

Dylan Humenik Ben Daily Srikrishnan Varadarajan Double Cart Collisions

CONSERVATION of MOMENTUM

SMART CART CONSERVATION OF MOMENTUM

Momentum & Energy Review Checklist

Experiment P-9 An Inclined Plane

Momentum in Collisions

Physics 103 Laboratory Fall Lab #2: Position, Velocity and Acceleration

PHYSICS MINI-LAB2.4: Culminating Example for Unit 2: Mathematical Toolkit

Activity P08: Newton's Second Law - Constant Force (Force Sensor, Motion Sensor)

Theory An important equation in physics is the mathematical form of Newton s second law, F = ma

Representations of Motion in One Dimension: Speeding up and slowing down with constant acceleration

frictionless horizontal surface. The bullet penetrates the block and emerges with a velocity of o

AP Physics C. Work and Energy. Free-Response Problems. (Without Calculus)

Impulse and Change in Momentum

Part One Inelastic Collision:

Constant velocity and constant acceleration

Welcome back to Physics 211

Impulse and Conservation of Momentum

ENERGYand WORK (PART I and II) 9-MAC

Lab 4 Motion in One-Dimension Part 2: Position, Velocity and Acceleration Graphically and Statistically (pre-requisite Lab3)

Impulse, Momentum, and Energy

Newton s Second Law. Computer with Capstone software, motion detector, PVC pipe, low friction cart, track, meter stick.

UNIT 4 NEWTON S THIRD LAW, FORCE DIAGRAMS AND FORCES. Objectives. To understand and be able to apply Newton s Third Law

MASSACHUSETTS INSTITUTE OF TECHNOLOGY Physics Department. Physics 8.01L IAP Experiment 3: Momentum and Collisions

Collisions Impulse and Momentum

PHY 111L Activity 2 Introduction to Kinematics

Welcome back to Physics 211

The diagram below shows a block on a horizontal frictionless surface. A 100.-newton force acts on the block at an angle of 30. above the horizontal.

UNIT 9 ENERGY. Objectives. To understand the concept of kinetic energy. To understand the relationship of net work to the change in kinetic energy

Conservation of Linear Momentum

Extra credit assignment #4 It can be handed in up until one class before Test 4 (check your course outline). It will NOT be accepted after that.

MASSACHUSETTS INSTITUTE OF TECHNOLOGY Physics Department. Experiment 03: Work and Energy

MASSACHUSETTS INSTITUTE OF TECHNOLOGY Physics Department. Physics 8.01 Fall Term 2006

Conservation of Momentum Using PASCO TM Carts and Track to Study Collisions in One Dimension

s_3x03 Page 1 Physics Samples

Experiment P14: Collision Impulse & Momentum (Force Sensor, Motion Sensor)

Problem Set 9: Momentum and Collision Theory : Solutions

(A) 0 (B) mv (C) 2mv (D) 2mv sin θ (E) 2mv cos θ

Physics experiments using the ScienceWorkshop or DataStudio program and interfaces from PASCO scientific

Lab 7. Newton s Third Law and Momentum

Recall: Gravitational Potential Energy

Straight Line Motion (Motion Sensor)

(A) I only (B) III only (C) I and II only (D) II and III only (E) I, II, and III

Experiment P17: Conservation of Linear Momentum II (Photogate)

Regents Physics. Physics Midterm Review - Multiple Choice Problems

Conservation of Energy

Energy Storage and Transfer: Gravitational Energy. Evaluation copy. Vernier Photogate (Extension only)

Extra Circular Motion Questions

Conservation of Energy

2. How will we adjust our fitting procedure to compensate for fact that the acceleration differs depending on the direction of motion?

Experiment P09: Acceleration of a Dynamics Cart I (Smart Pulley)

Activity P20: Conservation of Mechanical Energy (Force Sensor, Photogate)

Section 4.9: Investigating Newton's Second Law of Motion

Session 12 Lab Based Questions

Experiment: Momentum & Impulse in Collisions (Video)

Conservation of Energy and Momentum

Lab 11: Rotational Dynamics

Which force causes the path of the stream of water to change due to the plastic rod? A) nuclear B) magnetic C) electrostatic D) gravitational

Impulse and Momentum

Activity P10: Atwood's Machine (Photogate/Pulley System)

Name Class Date. Activity P21: Kinetic Friction (Photogate/Pulley System)

Electrostatic Charge Distribution (Charge Sensor)

L03 The Coefficient of Static Friction 1. Pre-Lab Exercises

Incline Plane Activity

Conservation of Linear Momentum

The work-energy theorem

(D) Based on Ft = m v, doubling the mass would require twice the time for same momentum change

UNIT 2 ONE-DIMENSIONAL FORCES AND MOTION. Objectives. To devise a method for applying a constant force to an object.

1D Motion: Review Packet Problem 1: Consider the following eight velocity vs. time graphs. Positive velocity is forward velocity.

AP Physics C: Mechanics Practice (Systems of Particles and Linear Momentum)

LAB 3: WORK AND ENERGY

Lab 12 - Conservation of Momentum And Energy in Collisions

Teacher s notes 13 Motion up and down an inclined plane

Simple Harmonic Motion Investigating a Mass Oscillating on a Spring

Period: Date: Review - UCM & Energy. Page 1. Base your answers to questions 1 and 2 on the information and diagram below.

Lab 3 Momentum Change and Impulse

Chapter 13. Simple Harmonic Motion

Kinematics. Become comfortable with the data aquisition hardware and software used in the physics lab.

2 possibilities. 2.) Work is done and... 1.) Work is done and... *** The function of work is to change energy ***

Elastic and Inelastic Collisions

PHY 221 Lab 7 Work and Energy

Lab 8. Work and Energy

RELEASED. Go to next page. 2. The graph shows the acceleration of a car over time.

Kinetic Energy and Work

General Physics I Lab (PHYS-2011) Experiment MECH-2: Newton's Second Law

Video Analysis Inertial and non-inertial reference frames

1 D Collisions and Impulse

CP Snr and Hon Freshmen Study Guide

Conservation of momentum in a central elastic collision with the demonstration track and timer 4 4

spacecraft mass = kg xenon ions speed = m s 1 Fig. 2.1 Calculate the mass of one xenon ion. molar mass of xenon = 0.

Unit 5: Momentum. Vocabulary: momentum, impulse, center of mass, conservation of momentum, elastic collision, inelastic collision.

Name 09-MAR-04. Work Power and Energy

Problem Set 9: Momentum and Collision Theory. Nov 1 Hour One: Conservation Laws: Momentum and Collision Theory. Reading: YF

Transcription:

Physics Demonstration Lab#6.6: The Impulse-Momentum and Work- Kinetic Energy Theorems For a Single Object on the Air Track Name: Date: EQUIPMENT PASCO Scientific Air Track and Accessories PASCO Scientific Force and Motion Sensors PASCO Scientific Science PowerLink Interface Personal Computer with PASCO DataStudio Software PURPOSE The purpose of this activity is to demonstrate how the Impulse-Momentum and Work- Kinetic Energy Theorems can be utilized to analyze interactions between an object and its surroundings. THEORY Impulse-Momentum Theorem: The change in momentum for an object is always equal to the total impulse acting on the object during a given time interval. If the net force is constant, the total impulse is equal to the product of the net force and the time interval over which the net force acts: F t m v v ) net ( f i If the net force varies over the time that the net force acts on the object, then the total impulse may be found most effectively by determining area under the force-time graph. Work-Kinetic Energy Theorem: The change in kinetic energy of an object is equal to the net work done on the object as it moves over a given distance. If the net force is constant, the net work is equal to the product of the net force and the distance over which the net force acts: F net 1 2 2 f Vi d m( V 2 If the net force varies over the distance that the net force acts on the object, then the net work is equal to the area under a force-distance. Useful Definitions: Impulse-Momentum Theorem: o Impulse = Area under force-time graph (constant force => Impulse = force*time) o Momentum = mass*velocity o Total Impulse = Change in Momentum o Units: N*sec = kg*m/sec Work-Kinetic Energy Theorem: o Work = Area under force-distance graph (constant force => Work = force*distance) o Kinetic Energy = ½ * mass * speed^2 o Net Work = Change in Kinetic Energy o Units: N*m = kg*m^2/sec^2 = J (Joule) )

PROCEDURE Case#1 - Constant Net Force: Consider the apparatus illustrated below: Record the Mass of Air-Track Cart and the Angle of Track. Collect data as the Air-Track Cart travels down the incline using DataStudio and compare those results with the enclosed graphs, which were collected earlier for this case. Motion Sensor Air-Track Cart Case#2 - Variable Net Force - Elastic Rebound: Consider the apparatus illustrated below: Record the Mass of Air-Track Cart / Magnet. Collect data as the Air-Track Cart travels along the air track and rebounds off the magnet attached to the force sensor and compare those results with the enclosed graphs, which were collected earlier for this case. Motion Sensor Air-Track Cart / Magnet Magnet / Force Sensor DATA Case#1 - Constant Net Force: Mass of Air-Track Cart: kg Angle of Track: degrees Graphs for earlier run: Position-Time, Velocity-Time, Acceleration-Time Case#2 - Variable Net Force - Elastic Rebound: Mass of Air-Track Cart: kg Angle of Track: degrees Graphs for earlier run: Position-Time, Velocity-Time, Acceleration-Time, Force- Time, and Force-Position

ANALYSIS/CONCLUSIONS: Case#1 - Constant Net Force: Illustrate the forces and the angle of the track to create a Free-Body Diagram for the Air Track Cart Find the Net Force (component of gravity in direction of motion) algebraically Verify that the Force-Time and Force-Distance graphs are consistent with the other data Calculate the change in momentum using mass and velocity data Calculate the impulse using the Impulse-Momentum Theorem Calculate the impulse by calculating the area under the Force-Time Graph Calculate the change in kinetic energy Calculate the work using the Work-Kinetic Energy Theorem Calculate the work by calculating the area under the Force-Distance Graph Complete the following statements by filling in the blank as appropriate: The Impulse-Momentum Theorem supported by this experiment. The Work-Kinetic Energy Theorem supported by this experiment.

Case#2 - Variable Net Force - Elastic Rebound: Illustrate relevant forces on the diagrams below to create Free-Body Diagrams for the time-frames indicated: cart moves at constant velocity along the track cart is being pushed backward by the magnet attached to the force sensor Calculate the change in momentum during the entire rebound from the mass and velocity data Estimate the total impulse during the entire rebound by approximating the area under the Force-Time Graph Calculate the change in kinetic energy during the first half of the rebound (as the cart is brought to rest by the magnetic force) Estimate the net work done during the first half of the rebound (as the cart is brought to rest by the magnetic force) by approximating the area under the Force- Distance Graph Complete the following statements by filling in the blank as appropriate: The Impulse-Momentum Theorem supported by this experiment. The Work-Kinetic Energy Theorem supported by this experiment.

Case#1 - Constant Net Force:

Case#2 - Variable Net Force - Elastic Rebound:

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback