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Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

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Mr. Jean Mr. Jean November 21 November 21 st st , 2013 , 2013 IB Physics 11 IB Physics 11
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Page 1: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Mr. JeanMr. Jean

November 21November 21stst, 2013, 2013

IB Physics 11IB Physics 11

Page 2: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

The plan:The plan:

Video clip of the dayVideo clip of the day Potential EnergyPotential Energy Kinetic EnergyKinetic Energy Restoring forcesRestoring forces Hooke’s LawHooke’s Law Elastic Potential EnergyElastic Potential Energy

Page 3: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Who has the most EWho has the most Ekk and by how much more? and by how much more?

Page 4: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

How much kinetic energy does each How much kinetic energy does each racer have?racer have?

Page 5: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Try This: Try This: Prove that work, Potential Energy, and Prove that work, Potential Energy, and

Kinetic energy are the same for the Kinetic energy are the same for the following:following: A block sitting at 0meters is slide up a A block sitting at 0meters is slide up a

frictionless inclined plane to a height of 80 frictionless inclined plane to a height of 80 meters. The block is then held in place for 50 meters. The block is then held in place for 50 minutes. The block is then released. minutes. The block is then released.

Page 6: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.
Page 7: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.
Page 8: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Elastic Potential Energy in SpringsElastic Potential Energy in Springs

If you pull on a spring and If you pull on a spring and stretch it out, you do work stretch it out, you do work on the spring.on the spring.

W = FdW = Fd Since work is a transfer of Since work is a transfer of

energy, then energy must energy, then energy must be transferred into the be transferred into the spring.spring.

Page 9: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Work becomes stored in the Work becomes stored in the spring as potential energy.spring as potential energy.

When you stretch a spring, it When you stretch a spring, it has the potential to “spring” has the potential to “spring” back. This is stored energy.back. This is stored energy.

When you compress a spring, When you compress a spring, it has the potential to “spring” it has the potential to “spring” forwards. This is stored forwards. This is stored energy.energy.

Page 10: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Work & Elastic Potential Energy:Work & Elastic Potential Energy:

EEee = ½ k x = ½ k x22

EEee = elastic potential energy in J (joules) = elastic potential energy in J (joules)

k = spring constant N/m (newtons per meters)k = spring constant N/m (newtons per meters) x = length of extension m (meters)x = length of extension m (meters)

Page 11: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Energy Stored in a SpringEnergy Stored in a Spring If a spring’s stretch/compression is directly If a spring’s stretch/compression is directly

proportional to the the amount of force applied proportional to the the amount of force applied to it then the elastic potential energy stored in a to it then the elastic potential energy stored in a spring is given by:spring is given by:

Where x is the Where x is the DISTANCEDISTANCE the spring is the spring is stretched or compressedstretched or compressed

K is called a “spring constant”. K is called a “spring constant”.

2

2

1kxEe

Page 12: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.
Page 13: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

If a spring is not stretched or compressed, then If a spring is not stretched or compressed, then there is no energy stored in it.there is no energy stored in it.

It is in its equilibrium position. (it’s natural It is in its equilibrium position. (it’s natural position)position)

Page 14: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

ProblemProblem It requires 100 J of work to stretch a spring It requires 100 J of work to stretch a spring

out 0.10 m. Find the spring constant of out 0.10 m. Find the spring constant of the spring.the spring.

Page 15: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

kmJ

km

J

mkJ

mkJ

kxEe

2

2

2

2

2

/20000

010.0

200

)010.0(200

)10.0(2

1100

2

1

Page 16: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Hookes Law:Hookes Law: The force exerted by a The force exerted by a spring is proportional to the distance spring is proportional to the distance the spring is stretched or compressed the spring is stretched or compressed from its relaxed position.from its relaxed position.

FFXX = -k x = -k x Where Where xx is the displacement from is the displacement from the the

relaxed position and relaxed position and kk is the is the constant of constant of proportionality.proportionality.

(often called “spring constant”)(often called “spring constant”)

x > 0

Page 17: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Conservation of Energy:Conservation of Energy:

m

y

y=0

m

xx=0

Etotal = 1/2 mv2 + 1/2 kx2 = constant

KE PE

Page 18: Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Hooke’s Law Investigation:Hooke’s Law Investigation:

Start Hooke’s Law InvestigationStart Hooke’s Law Investigation


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