potential energy
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Transcript potential energy
Chapter 7
Potential Energy
Potential Energy
Potential energy is the energy
associated with the configuration of a
system of objects that exert forces on
each other
The forces are internal to the system
Types of Potential Energy
There are many forms of potential
energy, including:
Gravitational
Electromagnetic
Chemical
Nuclear
One form of energy in a system can be
converted into another
System Example
This system consists
of Earth and a book
Do work on the
system by lifting the
book through Dy
The work done is
mgyb - mgya
Potential Energy
The energy storage mechanism is
called potential energy
A potential energy can only be
associated with specific types of forces
Potential energy is always associated
with a system of two or more interacting
objects
Gravitational Potential Energy
Gravitational Potential Energy is
associated with an object at a given
distance above Earth’s surface
Assume the object is in equilibrium and
moving at constant velocity
The work done on the object is done by
and the upward displacement is
Gravitational Potential Energy,
cont
The quantity mgy is identified as the
gravitational potential energy, Ug
Ug = mgy
Units are joules (J)
Gravitational Potential Energy,
final
The gravitational potential energy depends
only on the vertical height of the object above
Earth’s surface
In solving problems, you must choose a
reference configuration for which the
gravitational potential energy is set equal to
some reference value, normally zero
The choice is arbitrary because you normally need
the difference in potential energy, which is
independent of the choice of reference
configuration
Conservation of Mechanical
Energy
The mechanical energy of a system is the
algebraic sum of the kinetic and potential
energies in the system
Emech = K + Ug
The statement of Conservation of Mechanical
Energy for an isolated system is Kf + Ugf = Ki+
Ugi
An isolated system is one for which there are no
energy transfers across the boundary
Conservation of Mechanical
Energy, example
Look at the work done
by the book as it falls
from some height to a
lower height
Won book = DKbook
Also, W = mgyb – mgya
So, DK = -DUg
Cons Of Pendulum and Spring
AF_0706 conservation of mechanical
energy in a block-spring system.swf
AF_0715 an oscillating block-spring
system.swf
AF_0715b conservation of mechanical
energy for a pendulum.swf
AF_0703 projectiles launched at
different angles.swf
Conservative Forces
A conservative force is a force between
members of a system that causes no
transformation of mechanical energy within
the system
The work done by a conservative force on a
particle moving between any two points is
independent of the path taken by the particle
The work done by a conservative force on a
particle moving through any closed path is
zero
Nonconservative Forces
A nonconservative force does not
satisfy the conditions of conservative
forces
Nonconservative forces acting in a
system cause a change in the
mechanical energy of the system
Nonconservative Force,
Example
Friction is an
example of a
nonconservative
force
The work done
depends on the path
The red path will
take more work than
the blue path
Elastic Potential Energy
Elastic Potential Energy is associated
with a spring, Us = 1/2 k x2
The work done by an external applied
force on a spring-block system is
W = 1/2 kxf2 – 1/2 kxi2
The work is equal to the difference
between the initial and final values of an
expression related to the configuration of
the system
Elastic Potential Energy, cont
This expression is the
elastic potential energy:
Us = 1/2 kx2
The elastic potential
energy can be thought
of as the energy stored
in the deformed spring
The stored potential
energy can be
converted into kinetic
energy
Elastic Potential Energy, final
The elastic potential energy stored in a spring
is zero whenever the spring is not deformed
(U = 0 when x = 0)
The energy is stored in the spring only when the
spring is stretched or compressed
The elastic potential energy is a maximum
when the spring has reached its maximum
extension or compression
The elastic potential energy is always positive
x2 will always be positive
Conservation of Energy,
Extended
Including all the types of energy
discussed so far, Conservation of
Energy can be expressed as
DK + DU + DEint = DE system = 0 or
K + U + E int = constant
K would include all objects
U would be all types of potential energy
Problem Solving Strategy –
Conservation of Mechanical Energy
Conceptualize: Define the isolated
system and the initial and final
configuration of the system
The system may include two or more
interacting particles
The system may also include springs or
other structures in which elastic potential
energy can be stored
Also include all components of the system
that exert forces on each other
Problem-Solving Strategy, 2
Categorize: Determine if any energy
transfers across the boundary
If it does, use the nonisolated system
model, DE system = ST
If not, use the isolated system model,
DEsystem = 0
Determine if any nonconservative forces
are involved
Problem-Solving Strategy, 3
Analyze: Identify the configuration for
zero potential energy
Include both gravitational and elastic
potential energies
If more than one force is acting within the
system, write an expression for the
potential energy associated with each force
Problem-Solving Strategy, 4
If friction or air resistance is present,
mechanical energy of the system is not
conserved
Use energy with non-conservative
forces instead
The difference between initial and final
energies equals the energy transformed to
or from internal energy by the
nonconservative forces
Problem-Solving Strategy, 5
If the mechanical energy of the system
is conserved, write the total energy as
Ei = Ki + Ui for the initial configuration
Ef = Kf + Uf for the final configuration
Since mechanical energy is conserved,
Ei = Ef and you can solve for the
unknown quantity
Mechanical Energy and
Nonconservative Forces
In general, if friction is acting in a
system:
DEmech = DK + DU = -ƒkd
DU is the change in all forms of potential
energy
If friction is zero, this equation becomes
the same as Conservation of Mechanical
Energy
Nonconservative Forces,
Example 1 (Slide)
DEmech = DK + DU
DEmech =(Kf – Ki) +
(Uf – Ui)
DEmech = (Kf + Uf) –
(Ki + Ui)
DEmech = 1/2 mvf2 –
mgh = -ƒkd
Nonconservative Forces,
Example 2 (Spring-Mass)
Without friction, the
energy continues to be
transformed between
kinetic and elastic
potential energies and
the total energy remains
the same
If friction is present, the
energy decreases
DEmech = -ƒkd
Conservative Forces and
Potential Energy
Define a potential energy function, U,
such that the work done by a
conservative force equals the decrease
in the potential energy of the system
The work done by such a force, F, is
DU is negative when F and x are in the
same direction
Conservative Forces and
Potential Energy
The conservative force is related to the
potential energy function through
The conservative force acting between parts
of a system equals the negative of the
derivative of the potential energy associated
with that system
This can be extended to three dimensions
Conservative Forces and
Potential Energy – Check
Look at the case of an object located
some distance y above some reference
point:
This is the expression for the vertical
component of the gravitational force
Nonisolated System in Steady
State
A system can be nonisolated with 0 =
DT
This occurs if the rate at which energy is
entering the system is equal to the rate at
which it is leaving
There can be multiple competing transfers
Nonisolated System in Steady
State, House Example
Potential Energy for
Gravitational Forces
Generalizing
gravitational potential
energy uses Newton’s
Law of Universal
Gravitation:
The potential energy
then is
Potential Energy for
Gravitational Forces, Final
The result for the earth-object system
can be extended to any two objects:
For three or more particles, this
becomes
Electric Potential Energy
Coulomb’s Law gives the electrostatic
force between two particles
This gives an electric potential energy
function of
Energy Diagrams and Stable
Equilibrium
The x = 0 position is
one of stable
equilibrium
Configurations of stable
equilibrium correspond
to those for which U(x)
is a minimum
x=xmax and x=-xmax are
called the turning points
Energy Diagrams and
Unstable Equilibrium
Fx = 0 at x = 0, so the
particle is in equilibrium
For any other value of
x, the particle moves
away from the
equilibrium position
This is an example of
unstable equilibrium
Configurations of
unstable equilibrium
correspond to those for
which U(x) is a
maximum
Neutral Equilibrium
Neutral equilibrium occurs in a
configuration when U is constant over
some region
A small displacement from a position in
this region will produce neither restoring
nor disrupting forces
Potential Energy in Fuels
Fuel represents a storage mechanism
for potential energy
Chemical reactions release energy that
is used to operate the automobile