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REVIEW & SUMMARY 199

Substituting Eqs. 8-43 through 8-45 into Eq. 8-42, we find

0  kd^2 mghmkmgL, (8-46)

and

L

69.3 m. (Answer)

Finally, note how algebraically simple our solution is. By

carefully defining a system and realizing that we have an

isolated system, we get to use the law of the conservation of

energy. That means we can relate the initial and final states

of the system with no consideration of the intermediate

states. In particular, we did not need to consider the glider as

it slides over the uneven track. If we had, instead, applied

Newton’s second law to the motion, we would have had to

know the details of the track and would have faced a far

more difficult calculation.



(3.20 103 N/m)(5.00 m)^2

2(0.800)(200 kg)(9.8 m/s^2 )



35 m

0.800



kd^2

2 mkmg



h

mk

1

2

Conservative Forces A force is a conservative forceif the net
work it does on a particle moving around any closed path, from an
initial point and then back to that point, is zero. Equivalently, a
force is conservative if the net work it does on a particle moving
between two points does not depend on the path taken by the par-
ticle. The gravitational force and the spring force are conservative
forces; the kinetic frictional force is a nonconservative force.

Potential Energy Apotential energyis energy that is associated
with the configuration of a system in which a conservative force acts.
When the conservative force does work Won a particle within the sys-
tem, the change Uin the potential energy of the system is

UW. (8-1)

If the particle moves from point xito point xf, the change in the
potential energy of the system is

(8-6)

Gravitational Potential Energy The potential energy asso-
ciated with a system consisting of Earth and a nearby particle is
gravitational potential energy.If the particle moves from height yi
to height yf, the change in the gravitational potential energy of the
particle–Earth system is

Umg(yfyi)mgy. (8-7)

If the reference pointof the particle is set as yi0 and the cor-
responding gravitational potential energy of the system is set as
Ui0, then the gravitational potential energy Uwhen the parti-

U

xf

xi

F(x)dx.

Review & Summary

cle is at any height yis

U(y)mgy. (8-9)

Elastic Potential Energy Elastic potential energy is the

energy associated with the state of compression or extension of an

elastic object. For a spring that exerts a spring force Fkxwhen

its free end has displacement x, the elastic potential energy is

(8-11)

The reference configurationhas the spring at its relaxed length, at

whichx0 and U0.

Mechanical Energy The mechanical energyEmecof a system

is the sum of its kinetic energy Kand potential energy U:

EmecKU. (8-12)

Anisolated systemis one in which no external forcecauses energy

changes. If only conservative forces do work within an isolated sys-

tem, then the mechanical energy Emecof the system cannot change.

This principle of conservation of mechanical energyis written as

K 2 U 2 K 1 U 1 , (8-17)

in which the subscripts refer to different instants during an

energy transfer process. This conservation principle can also be

written as

EmecKU0. (8-18)

Potential Energy Curves If we know the potential energy

functionU(x) for a system in which a one-dimensional force F(x)

U(x)^12 kx^2.

In the final state, with the spring now in its relaxed state and
the glider again stationary but no longer elevated, the final
mechanical energy of the system is

Emec,2 K 2 Ue 2 Ug 2

 0  0 0. (8-44)

Let’s next go after the change Ethof the thermal energy of
the glider and ground-level track. From Eq. 8-31, we can
substitute for EthwithfkL(the product of the frictional
force magnitude and the distance of rubbing). From Eq. 6-2,
we know that fk mkFN, where FNis the normal force.
Because the glider moves horizontally through the region
with friction, the magnitude of FNis equal to mg(the up-
ward force matches the downward force). So, the friction’s
theft from the mechanical energy amounts to

Eth mkmgL. (8-45)

(By the way, without further experiments, we cannotsay
how much of this thermal energy ends up in the glider and
how much in the track. We simply know the total amount.)