PROGRAM OF “PHYSICS”
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Transcript of PROGRAM OF “PHYSICS”
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PROGRAM OF PROGRAM OF “PHYSICS”“PHYSICS”Lecturer: Dr. DO Xuan Hoi
Room 413E-mail : [email protected]
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PHYSICS I PHYSICS I (General Mechanics) (General Mechanics)
02 credits (30 periods)02 credits (30 periods)
Chapter 1 Bases of KinematicsChapter 1 Bases of Kinematics
Motion in One Dimension Motion in One Dimension
Motion in Two DimensionsMotion in Two Dimensions
Chapter 2 The Laws of Motion Chapter 2 The Laws of Motion
Chapter 3 Work and Mechanical EnergyChapter 3 Work and Mechanical Energy
Chapter 4 Linear Momentum and CollisionsChapter 4 Linear Momentum and Collisions
Chapter 5 Rotation of a Rigid Object Chapter 5 Rotation of a Rigid Object About a Fixed Axis About a Fixed Axis
Chapter 6 Static EquilibriumChapter 6 Static Equilibrium
Chapter 7 Universal GravitationChapter 7 Universal Gravitation
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References :References :
Halliday D., Resnick R. and Walker, J. Halliday D., Resnick R. and Walker, J. (2005), Fundamentals of Physics, (2005), Fundamentals of Physics, Extended seventh edition. John Willey Extended seventh edition. John Willey and Sons, Inc.and Sons, Inc.
Alonso M. and Finn E.J. (1992). Physics, Alonso M. and Finn E.J. (1992). Physics, Addison-Wesley Publishing CompanyAddison-Wesley Publishing Company
Hecht, E. (2000). Physics. Calculus, Second Hecht, E. (2000). Physics. Calculus, Second Edition. Brooks/Cole.Edition. Brooks/Cole.
Faughn/Serway (2006), Serway’s College Faughn/Serway (2006), Serway’s College Physics, Brooks/Cole.Physics, Brooks/Cole.
Roger Muncaster (1994), A-Level Physics, Roger Muncaster (1994), A-Level Physics, Stanley Thornes.Stanley Thornes.
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http://ocw.mit.edu/OcwWeb/Physics/index.htmhttp://www.opensourcephysics.org/index.htmlhttp://hyperphysics.phy-astr.gsu.edu/hbase/HFrame.htmlhttp://www.practicalphysics.org/go/Default.htmlhttp://www.msm.cam.ac.uk/http://www.iop.org/index.html...
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PHYSICS IPHYSICS IChapter 4Chapter 4
Linear Momentum and CollisionsLinear Momentum and Collisions
Linear Momentum and Its Conservation
Collisions in One Dimension
Two-Dimensional Collisions
The Center of Mass
Motion of a System of Particles
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1 1 Linear Momentum and Its Conservation From Newton’s laws: force must be present to From Newton’s laws: force must be present to
change an object’s velocity (speed and/or direction)change an object’s velocity (speed and/or direction)Wish to consider effects of collisions and Wish to consider effects of collisions and
corresponding change in velocitycorresponding change in velocity
Method to describe is to use concept of Method to describe is to use concept of linear linear momentummomentum
scalar vector
Linear momentum = product of mass velocityLinear momentum = product of mass velocity
Golf ball initially at rest, so some of the KE of club transferred to provide motion of golf ball and its change in velocity
p mv????????????????????????????
kg.m/kg.m/ss
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Linear momentumLinear momentum : Vector quantity : Vector quantity, the , the direction of the momentum is the same as the direction of the momentum is the same as the
velocity’svelocity’s
Applies to three-dimensional motion as wellApplies to three-dimensional motion as well; ;x x y y z zp mv p mv p mv
Force and linear Force and linear momentummomentum ( )dv d mv
F ma mdt dt
????????????????????????????
dp Fdt??????????????
Impulse :Impulse :f
i
t
t
I p dp F t ??????????????
dpF
dt
??????????????
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TestTest
Suppose a ping-pong ball and a bowling ball are rolling toward you. Both have the same momentum, and you exert the same force to stop each. How do the time intervals to stop them compare?
1. It takes less time to stop the ping-pong ball.2. Both take the same time.3. It takes more time to stop the ping-pong ball.
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EXAMPLE 1EXAMPLE 1
(a)
A 50-g golf ball at rest is hit by “Big Bertha” club with
500-g mass. After the collision, golf leaves with velocity of
50 m/s. (a) Find impulse imparted to ball(b) Assuming club in contact with ball for 0.5 ms,
find average force acting on golf ball
(b)
0.050 50 0 2.50kg m s kg m s fip mv mv
pF
t
33
2.505.00 10
0.5 10kg m s
Ns
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Conservation of momentum for a two-particle system
1 221 12
( ) ( );
d p d pF F
dt dt
Newton’s third law :
Consider two particles 1 and 2 interacting with each other :
21 12 ;F F
1 2( ) ( )d p d pdt dt
1 2( )0 ;
d p pdt
1 2p p const
In general, for an isolated system :
ii
p const
Whenever two or more particles in an isolated system
interact, the total momentum of the system remains constant
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EXAMPLE 2EXAMPLE 2
The initial momentum of the system:
The final momenta of the two pieces:
One-dimensional explosion: A box with mass m = 6.0 kg slides with speed v = 4.0 m/s across africtionless floor in the positive direction of an x axis.The box explodes into two pieces. One piece, with mass m1 = 2.0 kg, moves in the positive direction of the x axisat v1 = 8.0 m/s.What is the velocity of the second piece?
1 1 2 2fp mv mv ip mv
1 1 2 2mv mv mv ;i fp p
2
(6.0 )(4.0 / ) (2.0 )(8.0 / )2.0 /
4.0kg m s kg m s
v m skg
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2 2 Collisions in One Dimension
a. a. Collisions
A cA collisions is a event of two particles’ coming together for
a short time and thereby producing impulsive forces on
each other
The total momentum of an isolated system just before a
collision equals the total momentum of the system just after
the collision
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PROBLEM 1
A car of mass 1800 kg stopped at a traffic light is struck fromthe rear by a 900-kg car, and the two become entangled. Ifthe smaller car was moving at 20.0 m/s before the collision,what is the velocity of the entangled cars after the collision?
SOLUTION
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b. Types of Collisionsb. Types of Collisions
Momentum is conserved in any collisionMomentum is conserved in any collision
What about kinetic energy?What about kinetic energy?
InelasticInelastic collisions collisionsKinetic energy is Kinetic energy is notnot conserved : conserved :
Some of the kinetic energy is converted into other Some of the kinetic energy is converted into other types of energy such as heat, sound, work to types of energy such as heat, sound, work to permanently deform an objectpermanently deform an object
Perfectly inelasticPerfectly inelastic collisions occur when the collisions occur when the objects objects stick togetherstick together
Not all of the KE is necessarily lostNot all of the KE is necessarily lost
lost energyi fKE KE
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Perfectly Inelastic Collisions:Perfectly Inelastic Collisions:
► When two objects stick together after When two objects stick together after the collision, they have undergone a the collision, they have undergone a perfectly inelastic collisionperfectly inelastic collision
► Suppose, for example, vSuppose, for example, v2i 2i = 0. = 0. Conservation of momentum becomesConservation of momentum becomes
1 1 2 2 1 2( )i i fmv mv m m v
1 2
4
3
E.g., if 1000 , 1500 :
(1000 )(50 ) 0 (2500 ) ,
5 1020 .
2.5 10
f
f
m kg m kg
kg m s kg v
kg m sv m s
kg
1 1 1 20 ( )i fmv m m v
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Perfectly Inelastic Collisions:Perfectly Inelastic Collisions:
► What amount of KE lost What amount of KE lost during collision?during collision?
2 21 1 2 2
2 6
1 12 21
(1000 )(50 ) 1.25 102
before i iKE mv mv
kg m s J
21 2
2 6
1( )
21
(2500 )(20 ) 0.50 102
after fKE m m v
kg m s J
60.75 10lostKE J
lost in heat/”gluing”/sound/…
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ElasticElastic collisions collisions
both momentum and kinetic energy are both momentum and kinetic energy are conservedconserved
Typically have two unknownsTypically have two unknowns
Solve the equations simultaneouslySolve the equations simultaneously
1 1 2 2 1 1 2 2
2 2 2 21 1 2 2 1 1 2 2
1 1 1 12 2 2 2
i i ff
i i ff
mv mv mv mv
mv mv mv mv
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EXAMPLE 2EXAMPLE 2A block of mass m1 = 1.60 kg initially moving to the right
witha speed of 4.00 m/s on a frictionless horizontal track
collideswith a spring attached to a second block of mass m2 =
2.10 kginitially moving to the left with a speed of 2.50 m/s. The
springconstant is 600 N/m.(a) At the instant block 1 is moving to the right with a
speed of3.00 m/s, determine the velocity of block 2.
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EXAMPLE 2EXAMPLE 2A block of mass m1 = 1.60 kg initially moving to the right
witha speed of 4.00 m/s on a frictionless horizontal track
collideswith a spring attached to a second block of mass m2 =
2.10 kginitially moving to the left with a speed of 2.50 m/s. The
springconstant is 600 N/m.(b) Determine the distance the spring is compressed at
thatinstant.Conservation of mechanical
energy :
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2 2 Two-Dimensional Collisions
Momentum is conserved in any collision :Momentum is conserved in any collision :
1 1 2 2 1 1 2 2i i ffmv mv mv mv
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Problem Solving StrategyProblem Solving Strategy
Set up coordinate axes and define your velocities with Set up coordinate axes and define your velocities with respect to these axesrespect to these axes
It is convenient to choose the x axis to coincide with It is convenient to choose the x axis to coincide with one of the initial velocitiesone of the initial velocities
Draw and label all the velocities and include all the given Draw and label all the velocities and include all the given informationinformation
Write expressions for the total momentum before and after Write expressions for the total momentum before and after the collision in the x-directionthe collision in the x-direction
Repeat for the y-directionRepeat for the y-directionSolve for the unknown quantitiesSolve for the unknown quantities
If the collision is inelastic, additional information is If the collision is inelastic, additional information is probably requiredprobably required
If the collision is perfectly inelastic, the final velocities If the collision is perfectly inelastic, the final velocities of the two objects is the sameof the two objects is the same
If the collision is elastic, use the KE equations to help If the collision is elastic, use the KE equations to help solve for the unknownssolve for the unknowns
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PROBLEM 2
A 1 500-kg car traveling east with a speed of 25.0 m/s collidesat an intersection with a 2 500-kg van traveling north at a speed of20.0 m/s.Find the direction and magnitude of the velocity of the wreckage after the collision, assuming that the vehicles stick together after the collision.
SOLUTIONStick together : perfectly inelastic collision
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PROBLEM 2
A 1 500-kg car traveling east with a speed of 25.0 m/s collidesat an intersection with a 2 500-kg van traveling north at a speed of20.0 m/s.Find the direction and magnitude of the velocity of the wreckage after the collision, assuming that the vehicles stick together after the collision.
SOLUTION
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PROBLEM 3
In a game of billiards, a player wishes to sink a target ball 2 in the corner pocket as shown in the figure. If the angle to the corner pocket is 35°, at what angle is the cue ball 1 deflected?Assume that friction and rotational motion are unimportant and that the collision is elastic
SOLUTION
Conservation of energy :
1 2m m
Conservation of momentum :
(3)
(1)
(1) and (3) :
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PROBLEM 4
The figure shows two battling robots sliding on a frictionless surface. Robot A, with mass 20 kg, initially moves at 2.0 m/s parallel to the x-axis. It collides with robot B, which has mass 12 kg and is initially at rest. After the collision, robot A is moving at 1.0 m/s in a direction that makes an angle a = 30° with its initial direction. What is the final velocity of robot B?
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SOLUTION
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3. 3. The center of mass
The coordinates of the center of mass of n particles
x1
y1
x2
y2
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The position vector of the center of mass :
The coordinates of the center of mass of n particles
x1
y1
x2
y2
CM
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EXAMPLE 3EXAMPLE 3A system consists of three particles located as
shown inthe figure. Find the center of mass of the system.
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The center of mass of a symmetric system
CM CMCM
CM?
The center of mass of any symmetric object lies on an axis of symmetry and on any plane of symmetry.
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The center of mass of a rigid body
The vector position of the center of mass :
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An object of mass M is in the shape of a right triangle whose
dimensions are shown in the figure. Locate the coordinates of the
center of mass, assuming the object has a uniform mass per unit
area.
EXAMPLE 4EXAMPLE 4
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PROBLEM 5
The figure shows a simple model of the structure of a water mole- cule. The separation between atoms is d = 9.57 10-11 m. Each hydrogen atom has mass 1.0 u, and the oxygen atom has mass 16.0 u. Find the position of the center of mass.
SOLUTION
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PROBLEM 6
A uniform piece of sheet steel is shaped as shown in the figure. Compute the x and y coordinates of the center of mass of the piece
SOLUTION
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4 Motion of a System of Particles4 Motion of a System of ParticlesThe velocity of the center of mass of the system :
The acceleration of the center of mass of the system :
The center of mass of a system of particles of combined mass M moves like an equivalent particle of mass M would move under the influence of the resultant external force on the system