Newton’s Laws
MONDAY, September 14, Re-introduction to Newton’s 3 Laws
What is Force? A push or pull on an object. A push or pull on an object. Unbalanced forces cause an object to accelerate… Unbalanced forces cause an object to accelerate… To speed up To speed up To slow down To slow down To change direction To change direction Force is a vector! Force is a vector!
Types of Forces Contact forces: involve contact between bodies. Contact forces: involve contact between bodies. Normal, Friction Normal, Friction Field forces: act without necessity of contact. Field forces: act without necessity of contact. Gravity, Electromagnetic, Strong, Weak Gravity, Electromagnetic, Strong, Weak Dark side, light side, etc. Dark side, light side, etc.
Question: Is there really any such thing as a contact force? A. yea. B. No. C. I think this is a trick so I’m not answering.
If the net force on a body is zero then it must…. A. Be At rest B. Have a Constant Velocity C. Not be touching the ground D. Not be a jedi
Forces and Equilibrium If the net force on a body is zero, it is in equilibrium. If the net force on a body is zero, it is in equilibrium. An object in equilibrium may be moving relative to us (dynamic equilibrium). An object in equilibrium may be moving relative to us (dynamic equilibrium). An object in equilibrium may appear to be at rest (static equilibrium). An object in equilibrium may appear to be at rest (static equilibrium).
Galileo’s Thought Experiment
This thought experiment lead to Newton’s First Law. Galileo’s Thought Experiment © The Physics Classroom, Tom Henderson
Newton’s First Law The Law of Inertia. The Law of Inertia. A body at rest stays at rest unless acted upon by an external force A body at rest stays at rest unless acted upon by an external force A body in motion stays in motion in a straight line unless acted upon by an external force. A body in motion stays in motion in a straight line unless acted upon by an external force. Or.. Mass wants to do its thing. Or.. Mass wants to do its thing. This law is commonly applied to the horizontal component of velocity, which is assumed not to change during the flight of a projectile. This law is commonly applied to the horizontal component of velocity, which is assumed not to change during the flight of a projectile.
Note on Inertia Inertia is a property of matter. Inertia is a property of matter. Forget any definition of mass that you learned in Chemistry. Forget any definition of mass that you learned in Chemistry. Mass is a measure of an objects inertia. Mass is a measure of an objects inertia. It is the resistance to changes in motion It is the resistance to changes in motion
An objects mass cannot change unless you actually change the amount of matter present A. True- I believe in conservation of mass B. False- I am a non-believer and think it’s more complicated than that.
Newton’s Second Law A body accelerates when acted upon by a net external force A body accelerates when acted upon by a net external force The acceleration is proportional to the net (or resultant) force and is in the direction which the net force acts. The acceleration is proportional to the net (or resultant) force and is in the direction which the net force acts. This law is commonly applied to the vertical component of velocity. This law is commonly applied to the vertical component of velocity. F = ma F = ma
Newton’s Third Law For every action there exists an equal and opposite reaction. For every action there exists an equal and opposite reaction. If A exerts a force F on B, then B exerts a force of -F on A. If A exerts a force F on B, then B exerts a force of -F on A. Or Action Force = -Reaction Force Or Action Force = -Reaction Force
Commonly Confused Terms Inertia: or the resistance of an object to being accelerated Inertia: or the resistance of an object to being accelerated Mass: the same thing as inertia (to a physicist). Mass: the same thing as inertia (to a physicist). Weight: gravitational attraction Weight: gravitational attraction
We normally use the term “weightless” to describe the feeling that astronauts get when they are in orbit or in simulators like the Vomit Comet. What does “weightless” really mean when applied to these situations? A. You have no weight B. You have weight but it is not opposed by another force. C. You have no mass D. You have been eating dehydrated space food so you don’t weigh as much.
Only Two forces, F 1 and F 2 act upon a body of mass 3.0 kg. The body moves at constant speed. What do you know must be true? A. The net force must point in the direction of motion B. The object must be weightless. C. The vectors F 1 and F 2 must be 180° opposite each other. D. The sum of forces F 1 and F 2 must be zero
Two forces, F 1 = (4i – 6j + k) N and F 2 = (i – 2j - 8k) N, act upon a body of mass 3.0 kg. No other forces act upon the body at this time. What do you know must be true? A. The body’s motion will not change. B. The body’s motion will change. C. Today is Saturday. D. There must be another force.
A tug-of-war team ties a rope to a tree and pulls horizontally to create a tension of 30,000 N in the rope. Suppose the team pulls equally hard when, instead of a tree, the other end of the rope is being pulled by another tug-of-war team such that no movement occurs. What is the tension in the rope in the second case? A. Less than 30,000 N B. 30,000 N C. More than 30,000 N D. The rope will break
Working a 2 nd Law Problem Working Newton’s 2 nd Law Problems is best accomplished in a systematic fashion. Working Newton’s 2 nd Law Problems is best accomplished in a systematic fashion. The more complicated the problem, the more important it is to have a general procedure to follow in working it. The more complicated the problem, the more important it is to have a general procedure to follow in working it.
2 nd Law Procedure 1. Identify the body to be analyzed. 2. Select a reference frame, stationary or moving, but not accelerating (2 nd law holds for only inertial reference frames). 3. Draw a force or free body diagram. 4. Set up ΣF = ma equations for each dimension. 5. Use kinematics or calculus where necessary to obtain acceleration. 6. Substitute known quantities. 7. Calculate the unknown quantities.
A 5.00-g bullet leaves the muzzle of a rifle with a speed of 320 m/s. The bullet is accelerated by expanding gases while it travels down the m long barrel. Assuming constant acceleration and negligible friction, what is the force on the bullet? A. 160 N B. 320 N C. 640 N D N
A 3.00 kg mass undergoes an acceleration given by a = (2.50i j) m/s 2. Find the resultant force F and its magnitude. A. 4.8 N 59° from horizontal B N 31° from horizontal C. 4.8 N 31° from horizontal D N 59° from horizontal
Wednesday, September 17, 2009 Types of Forces Commonly Found in Newton’s Law Problems and Practice
Normal force The force that keeps one object from “invading” another object. The force that keeps one object from “invading” another object. Ex: weight is the force of attraction of our body for the center of the planet. Ex: weight is the force of attraction of our body for the center of the planet. We don’t fall to the center of the planet. We don’t fall to the center of the planet. The normal force keeps us up. The normal force keeps us up. It ALWAYS acts perpendicular to contact!!! NOT always vertical!!!! It ALWAYS acts perpendicular to contact!!! NOT always vertical!!!!
Normal Force on Flat surface
F n = -(mg) for objects resting on horizontal surfaces (no vertical acceleration). mg N
Normal Force on Ramp
mg The normal force is perpendicular to angled ramps as well. It’s usually equal to the component of weight perpendicular to the surface. N mgcos mgsin N = -(mgcos )
What will acceleration be in this situation? A.mgsin B.mgcos C.gsin D.gcos E.g N mgmg mgcos mgsin
Normal Force on Ramp mgmg How could you keep the block from accelerating? N mgcos mgsin N = -(mgcos ) F
Tension A pulling force. A pulling force. Generally exists in a rope, string, or cable. Generally exists in a rope, string, or cable. Arises at the molecular level, when a rope, string, or cable resists being pulled apart. Arises at the molecular level, when a rope, string, or cable resists being pulled apart.
Tension (static 2D) The horizontal and vertical components of the tension are equal to zero if the system is not accelerating. 15 kg 30 o 45 o 3 2 1
Tension (static 2D) The horizontal and vertical components of the tension are equal to zero if the system is not accelerating. 15 kg 30 o 45 o T1T1 T2T2 T3T3 F x = 0 F y = 0 -T 3 mgmg 3 2 1
A Mass m hangs by a cable from the bottom of an elevator. What is the tension in the cable when the elevator is stopped at a floor? A. g B. mg C. Greater in magnitude than mg D. Less magnitude than mg E. 0 m
Tension (elevator) The sum of the forces must be zero or the mass would accelerate! M T MgMg
A Mass m hangs by a cable from the bottom of an elevator. What is the tension in the cable when the elevator accelerates upward? A. g B. mg C. Greater in magnitude than mg D. Less magnitude than mg E. 0 m
Tension (elevator) T must be greater than mg in order to result in an upward acceleration! M T MgMg
A Mass m hangs by a cable from the bottom of an elevator. What is the tension in the cable when the elevator is moving at constant speed between floors? A. g B. mg C. Greater in magnitude than mg D. Less magnitude than mg E. 0 m
A Mass m hangs by a cable from the bottom of an elevator. What is the tension in the cable when the elevator is slowing down at the top floor? A. g B. mg C. Greater in magnitude than mg D. Less magnitude than mg E. 0 m
Tension (elevator) Net force must point down in order to accelerate down M T MgMg
A Mass m hangs by a cable from the bottom of an elevator. What will the tension in the cable be if it comes attached from the elevator? A. g B. mg C. Greater in magnitude than mg D. Less magnitude than mg E. 0 m
Tension (elevator) No opposing force! (weightless???) M MgMg
“Magic” pulleys simply bend the coordinate system. Pulley problems m1m1 m2m2
-x x “Magic” pulleys simply bend the coordinate system. Pulley problems m1m1 m2m2 m1gm1g N T T m2gm2g F = ma m2gm2g = (m 1 +m 2 )a
All problems should be started from a force diagram. Pulley problems m1m1 m2m2
Tension is determined by examining one block or the other Pulley problems m1m1 m2m2 m1gm1g N T T m2gm2g F m 1 +m 2 )a m 2 g – T+T – m 1 gsin = (m 1 +m 2 )a
Tension is determined by examining one block or the other Pulley problems m1m1 m2m2 m1gm1g N T T m2gm2g F 2 m 2 a m 2 g - T = m 2 a F 1 m 1 a m 1 gsin = m 1 a
Atwood machine A device for measuring g. A device for measuring g. If m1 and m2 are nearly the same, slows down freefall such that acceleration can be measured. If m1 and m2 are nearly the same, slows down freefall such that acceleration can be measured. Then, g can be measured. Then, g can be measured. m1m1 m2m2
Atwood machine A device for measuring g. A device for measuring g. If m1 and m2 are nearly the same, slows down freefall such that acceleration can be measured. If m1 and m2 are nearly the same, slows down freefall such that acceleration can be measured. Then, g can be measured. Then, g can be measured. m1m1 m2m2 T m1gm1g T m2gm2g F ma m 2 g-m 1 g = (m 2 +m 1 )a
Thursday, September 20, 2007 Post-Test Review
Friday, September 21, 2007 Workday Exam Corrections Homework Review
Atwood Machine Mini-lab Draw diagram of apparatus in lab book. Draw diagram of apparatus in lab book. Record all data. Record all data. Calculate g. Calculate g.
Easy Problem How fast will the block be sliding at the bottom of the frictionless ramp? 20 o L = 12 m 5.0 kg
Easy Problem How high up the frictionless ramp will the block slide? 5.0 kg 20 o v = 12.0 m/s
Tuesday, September 25, 2007 Friction
Moderate Problem Describe acceleration of the 5 kg block. Table and pulley are magic and frictionless. 20 o 5.0 kg 1.0 kg
Friction Friction opposes a sliding motion. Friction opposes a sliding motion. Static friction exists before sliding occurs Static friction exists before sliding occurs (f s s N). (f s s N). Kinetic friction exists after sliding occurs Kinetic friction exists after sliding occurs f k = k N f k = k N
Friction on flat surfaces x y Draw a free body diagram for a braking car. x y Draw a free body diagram for a car accelerating from rest.
But we don’t want cars to skid! Why don’t we? Why don’t we? Let’s use DataStudio to see if we can detect the difference in magnitude between static and kinetic friction. Let’s use DataStudio to see if we can detect the difference in magnitude between static and kinetic friction.
Wednesday, September 26, 2007 Friction Lab
Thursday, September 27, 2007
Friction on a ramp Sliding down Sliding up
Friction is always parallel to surfaces…. A 1.00 kg book is held against a wall by pressing it against the wall with a force of N. What must be the minimum coefficient of friction between the book and the wall, such that the book does not slide down the wall? FW f N (0.20)
Problem #1 Assume a coefficient of static friction of 1.0 between tires and road. What is the minimum length of time it would take to accelerate a car from 0 to 60 mph?
Problem #2 Assume a coefficient of static friction of 1.0 between tires and road and a coefficient of kinetic friction of 0.80 between tires and road. How far would a car travel after the driver applies the brakes if it skids to a stop?
Centripetal Force Inwardly directed force which causes a body to turn; perpendicular to velocity. Inwardly directed force which causes a body to turn; perpendicular to velocity. Centripetal force always arises from other forces, and is not a unique kind of force. Centripetal force always arises from other forces, and is not a unique kind of force. Sources include gravity, friction, tension, electromagnetic, normal. Sources include gravity, friction, tension, electromagnetic, normal. ΣF = ma ΣF = ma a = v 2 /r a = v 2 /r ΣF = m v 2 /r ΣF = m v 2 /r
Highway Curves R r z Friction turns the vehicle Normal force turns the vehicle
Sample problem Find the minimum safe turning radius for a car traveling at 60 mph on a flat roadway, assuming a coefficient of static friction of 0.70.
Sample problem Derive the expression for the period best banking angle of a roadway given the radius of curvature and the likely speed of the vehicles.
Friday, September 28, 2007 More on Circular Motion
Conical Pendulum For conical pendulums, centripetal force is provided by a component of the tension. z r T mgmg L T = 2 L cos g
Sample problem Derive the expression for the period of a conical pendulum with respect to the string length and radius of rotation.
Non-uniform Circular Motion Consider circular motion in which either speed of the rotating object is changing, or the forces on the rotating object are changing. Consider circular motion in which either speed of the rotating object is changing, or the forces on the rotating object are changing. If the speed changes, there is a tangential as well as a centripetal component to the force. If the speed changes, there is a tangential as well as a centripetal component to the force. In some cases, the magnitude of the centripetal force changes as the circular motion occurs. In some cases, the magnitude of the centripetal force changes as the circular motion occurs.
Sample problem You swing a 0.25-kg rock in a vertical circle on a 0.80 m long rope at 2.0 Hz. What is the tension in the rope a) at the top and b) at the bottom of your swing?
Monday, October 1 Time-dependent forces
Sample problem A 40.0 kg child sits in a swing supported by 3.00 m long chains. If the tension in each chain at the lowest point is 350 N, find a) the child’s speed at the lowest point and b) the force exerted by the seat on the child at the lowest point.
Sample problem A 900-kg automobile is traveling along a hilly road. If it is to remain with its wheels on the road, what is the maximum speed it can have as it tops a hill with a radius of curvature of 20.0 m?
Non-constant Forces Forces can vary with time. Forces can vary with time. Forces can vary with velocity. Forces can vary with velocity. Forces can vary with position. Forces can vary with position.
Calculus Concepts for Forces that Vary with Time Differentiation Differentiation the tangent (or slope) of a function the tangent (or slope) of a function position -> velocity -> acceleration position -> velocity -> acceleration Integration Integration the area under a curve the area under a curve acceleration -> velocity -> position acceleration -> velocity -> position
Evaluating Integrals If a(t) = t n then t n dt = t n+1 / (n+1) + C t n dt = t n+1 / (n+1) 0 t 0 t
Sample problem Consider a force that is a function of time: Consider a force that is a function of time: F(t) = (3.0 t – 0.5 t 2 )N If this force acts upon a 0.2 kg particle at rest for 3.0 seconds, what is the resulting velocity and position of the particle? If this force acts upon a 0.2 kg particle at rest for 3.0 seconds, what is the resulting velocity and position of the particle?
Sample problem Consider a force that is a function of time: Consider a force that is a function of time: F(t) = (16 t 2 – 8 t + 4)N If this force acts upon a 4 kg particle at rest for 1.0 seconds, what is the resulting change in velocity of the particle? If this force acts upon a 4 kg particle at rest for 1.0 seconds, what is the resulting change in velocity of the particle?
Drag Forces Drag forces Drag forces slow an object down as it passes through a fluid. slow an object down as it passes through a fluid. act in opposite direction to velocity. act in opposite direction to velocity. are functions of velocity. are functions of velocity. impose terminal velocity. impose terminal velocity.
Drag as a Function of Velocity f D = bv + cv 2 f D = bv + cv 2 b and c depend upon b and c depend upon shape and size of object shape and size of object properties of fluid properties of fluid b is important at low velocity b is important at low velocity c is important at high velocity c is important at high velocity
Drag Force in Free Fall mgmg mgmg fDfD mgmg fDfD mgmg fDfD when f D equals mg, terminal velocity has been reached
Drag Force in Free Fall for fast moving objects F D = c v 2 c = 1/2 D A Where D = drag coefficient = density of fluid A = cross-sectional area F D = bv + c v 2 for slow moving objects F D = b v mg FDFD
Sample Problem: Slow moving objects Show that v T = mg/b Show that v T = mg/b mg F D = bv
Sample Problem: Slow Moving Objects Show that v(t) = (mg/b)(1 – e –bt/m ) Show that v(t) = (mg/b)(1 – e –bt/m ) mg F D = bv
Sample Problem: Fast moving objects Show that v T = (2mg / D A) 1/2 Show that v T = (2mg / D A) 1/2 mg F D = 1/2D Av 2
Sample Problem: Fast moving objects Derive an expression for the velocity of the object as a function of time Derive an expression for the velocity of the object as a function of time mg F D = 1/2D Av 2