physics 2053c – fall 2001
DESCRIPTION
Physics 2053C – Fall 2001. Review for Final Exam http://www.hep.fsu.edu/~tadams. Important Topics. Kinematics Forces/Newton’s Laws Energy/Momentum Conservation Ideal Gases/Heat. Variable/Quantity/Units. ttimes xdistancem vvelocitym/s aaccelerationm/s 2 - PowerPoint PPT PresentationTRANSCRIPT
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Dec. 8, 2001Prof. Todd Adams,
FSU Department of Physics 1
Physics 2053C – Fall 2001
Review for Final Exam
http://www.hep.fsu.edu/~tadams
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Important Topics
Kinematics Forces/Newton’s Laws Energy/Momentum
Conservation Ideal Gases/Heat
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Variable/Quantity/Units
t time sx distance mv velocity m/sa acceleration m/s2 F force N = kg.m/s2 E energy J = N.mP power W = J.s
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Kinematics
Position Velocity – rate of change of position Acceleration – rate of change of
velocity Constant acceleration Constant velocity Constant position
a = 0v = 0, a = 0
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Equations of Motion
x = x0 + v0t + ½at2
v = v0 + at
v2 = v02 + 2a(x – x0)
x = positionx0 = initial positionv = velocityv0 = initial velocitya = accelerationt = time
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Forces
Force due to gravity Normal force Force due to friction Tension Buoyancy External force (e.g. a push)
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Gravity
• acceleration due to gravity (g = 9.80 m/s2)
• force due to gravity F = mg• Weight = force due to gravity• which direction???• Also, F = G.(m1m2)/r2
Newtons
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Types of Energy
Kinetic Linear K = ½mv2
Rotational Potential
Gravitational U = mgh Spring U = ½kx2
Internal Energy Heat Q = mcT Work W = Fdcos
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Ideal Gas Law
PV = nRTP = pressure (atm, bar,
N/m2)V = volume (m3)n = # of molesR = gas constantT = temperature (K)
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How to solve FORCE problems
1) Read the problem. (identify what you do and don’t know, look for “hidden” knowledge)
2) Draw a free-body diagram(identify all forces acting upon object)
3) Add all forces in one direction together (x?)F = F1 + F2 + F3 + …F = F1 + F2 + F3 + …
(determine sum of forces, maybe Fnet = 0 or Fnet = ma)
4) Add all forces in other direction together (y?)(determine sum of forces, maybe Fnet = 0 or Fnet = ma)
5) Solve for what you don’t know
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Sample Force Problem
The boxes are not moving.1) What is the value of T1?
2) What is the value of T2?
M1
M2
T2 T1
M1 = 20.0 kg M2 = 10.0 kg
= 0.3
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Sample Force Problem (cont)
F = T1 – Fg = 0
T1 = Fg
T1 = M2g = (10.0 kg)(9.80 m/s2)
T1 = 98.0 N
M1
M2
T2 T1
M1 = 20.0 kg M2 = 10.0 kg
= 0.3
M2
Fg
T1
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Sample Force Problem (cont)
Fy = FN – Fg = 0
FN = Fg
FN = M1g = (20.0 kg)(9.80 m/s2)
FN = 196.0 N
M1
M2
T2 T1
M1 = 20.0 kg M2 = 10.0 kg
= 0.3
M1
Fg
FN
T1T2
Ffr
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Sample Force Problem (cont)
Fx = T1 – T2 – Ffr = 0
T2 = T1 - Ffr
T2 = 98.0 N – (0.3)(196.0 N)
T2 = 39.2 N
M1
M2
T2 T1
M1 = 20.0 kg M2 = 10.0 kg
= 0.3
M1
Fg
FN
T1T2
Ffr
FN = 196.0 N
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Sample Force Problem (cont)
What if the boxes are moving with constant velocity?What if the boxes are accelerating at a = 2.2 m/s2?
What if we remove T2?
M1
M2
T2 T1
M1 = 20.0 kg M2 = 10.0 kg
= 0.3T1 = 98.0 NT2 = 39.2 N
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How to Solve ENERGY Problems
1) Identify types of energyKinetic?Gravitational Potential?Spring Potential?Heat?Internal Energy?Work?
2) Identify initial and final conditions3) Find unknown quantities:
W = K + U (if W 0)Ki + Ui = Kf + Uf (if W = 0)
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Sample Energy Problem
A 25 kg block is released from rest 5.5 m up a frictionless plane inclined at 30o. The block slides down the incline and along a horizontal surface. The horizontal surface has a coefficient of static friction of 0.32.
What is the velocity of the block at the bottom of the incline?
How far along the horizontal surface will the block slide?
5 m
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Sample Energy Problem (cont)
5 m
What kind of energies are present?
Kinetic energy
Gravitational potential energyWork done by friction
What is the energy at A?EA = KE + PE = 0 + mgh = mgdsin = (25 kg)(9.80 m/s2)(5 m)(sin 30o)EA = 612.5 J
AB C
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Sample Energy Problem (cont)
5 m
What is the energy at B?
EB = EA = 612.5 J
What happens to the energy as the box goes from A to B?
What is the velocity at B?EB = KE + PE = ½ mvB
2 + 0
vB = 7.0 m/s
AB C
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Sample Energy Problem (cont)
5 m
What happens to the energy as the box goes from B to C?What is the energy at C?
EC = 0.0 JHow far does the box slide?
W = KE + PE Wfr = Ffrd = FNd
W = (0.0 J – 612.5 J) + 0 J Wfr = mgd
W = Wfr .
. -612.5 J = (0.32)(25 kg)(9.8 m/s2)d = (78.4 N)d. d = (612.5 J)/(78.4 N) = 7.81 m
AB C
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How to Solve IDEAL GAS Problems
PV = nRT1) Identify initial and final conditions2) Take ratio
P1V1 n1RT1
P2V2 n2RT2
3) Cancel anything which is constant4) Solve for what you don’t know
=
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Sample Problem
What are the forces on the motorcycle as it accelerates (A)? What are the forces on the motorcycle as it moves at constant speed
(B,C)? How far does it travel while accelerating from rest to 30 m/s? What is the kinetic energy at points A, B, C? How much work is done by motorcycle? How much work is done by friction getting to A, B, C? What are the forces on the object as it moves upward from A to B?
M = 250 kg
0 to 30 m/s in 20 s
25 m
30 mF = 2500 N
V = 10 m/s
V = 18 m/s
A B C