ADV PHY Reviewer 2nd Quarter PDF

Summary

This document is a review of 2nd quarter concepts in physics, focusing on Newton's Law of Universal Gravitation and planetary motion.

Full Transcript

LEGAZPI CITY SCIENCE HIGHSCHOOL
9-CURIE
ADVANCE PHYSICS
Mrs. Analyn Fernandez

NEWTON’S LAW OF the masses. The constant G will remain the same
for any two objects anywhere in the Universe.
UNIVERSAL GRAVITATION G = 6.67x 10^-11 Nm^2/kg^2

TORSION BALANCE EXPERIMENT
WHAT MAKES US FALL ON THE EARTH ALWAYS?
There is always some force acting on us that Henry Cavendish’s experiment determined the
guides our direction of falling. proportionality constant G in 1798.
No matter from wherever we jump, or drop
objects from anywhere they will always fall
towards the earth.

WHAT MAKES THE APPLE ALWAYS FALL ON THE
EARTH?
It was Isaac Newton who posed this question
and answered it. Newton stated that all objects
attract each other along the line joining their
centers.

ISAAC NEWTON
1666, England (45 years after Kepler).

USES OF GRAVITATION
THE UNIVERSAL LAW OF GRAVITATION
It is the gravitational force that keeps everything
Every object in the universe in its place. Otherwise, we would have been
attracts every other object floating in the air.
towards itself It also keeps the Earth, sun, and other celestial
This force with which the bodies in their right places
two objects attract each other It is responsible for many natural phenomena on
is called the force of gravitation the earth like tides and orbiting of the moon
The force of gravitation acts even if nothing is around the earth.
connecting the two objects.
Newton did not stop after proposing that a force

of gravitation exists. He expressed the law in a KEPLER’S LAWS OF
clear and precise language- the language of
mathematics.
PLANETARY MOTION
TYCO BRAHE
THE UNIVERSAL LAW OF GRAVITATION STATES
THAT.. Danish astronomer Tyco Brahe
(1546-1601) had an island
Any two point particles with masses m1 and m2 observatory and the best
attract each other by a force whose magnitude is measurements of the
directly proportional to the product of the two positions for all known planets
masses, that is m1m2 and inversely proportional (Mercury, Venus, Mars, Jupiter,
to the square of the distance R between them. and Saturn) and the Moon.
The direction of the force is along the line joining
the two masses.
JOHANNES KEPLER
Austrian mathematician Johannes Kepler
(1571-1630), interested in how the planets move
around the sun, went to Tyco’s island to get these
accurate measurements.
G is a gravitational constant. It does not depend
on the value of masses or the distance between
LEGAZPI CITY SCIENCE HIGHSCHOOL
9-CURIE
ADVANCE PHYSICS
Mrs. Analyn Fernandez

WHAT IS AN ELIPSE? THIRD LAW
An ellipse is a geometric shape with 2 foci The square of the orbital period of a planet is
instead of 1 central focus, as in a circle. The sun is directly proportional to the cube of the average
at one focus with nothing at the other focus. distance of the planet from the sun.
2 3
T 1 = KR 1
K = 2.97 x 10-19 s2/m3

The farther a planet is from the focus, the longer
the period of revolution.

VERTICAL CIRCLES
Constant speed and direction of object.
Gravity either speeds up or slows down objects.

LAWS OF PLANETARY MOTION TOP OF THE CIRCLE
formula for calculating the tension in the string at the top
FIRST LAW of the circle

Planets move in elliptical Forces T and mg are downwards.
orbits with the sun at one NET FORCE must act towards the center of the
of the foci circle.
Centripetal force is the sum of two real forces.
Kepler also found that Fc should not be labeled in the free body
Mars changed speed as it diagram.
orbited around the sun:
faster when closer to the formula for calculating the minimum or critical velocity
sun, slower when farther needed for the block to just be able to pass through the
from the sun. But areas A top of the circle
and B, swept out by a line
from the sun to Mars, were equal over the same amount
of time. CRITICAL VELOCITY
velocity below which an object moving in a
SECOND LAW vertical circle will not describe a circular path.
A line from the sun to a Critical velocity depends on the acceleration due
planet sweeps out equal areas to gravity and the radius of the vertical circle,
in equal lengths of time. not on the mass of the object.
A planet will move through
an equal area of space in an BOTTOM OF THE CIRCLE
equal amount of time formula for calculating the tension in the string at the
bottom of the circle

Closer to the sun, the faster the velocity because Positive direction towards the center.
of the gravitational pull. Net Force acting towards the center: resultant
force or difference between T and mg.

Notice that the tension in the string is GREATEST as the
block passes through the bottom of the circle and LEAST
while it passes through the top of the circle.
LEGAZPI CITY SCIENCE HIGHSCHOOL
9-CURIE
ADVANCE PHYSICS
Mrs. Analyn Fernandez

Linear velocity of a point depends on:
Formula for calculating the tension at any intermediate
★ The rotational velocity of the point.
point in a pendulum’s swing
More rotational velocity means
more linear velocity.
★ The distance from the point to the axis
of rotation.
More distance from the axis
formula for calculating the normal force on the top of means more linear velocity.
the circle v = rɷ r = v/ɷ ɷ = v/r

ACCELERATION
formula for calculating the normal force on the bottom As an object moves around a circle, its direction
of the circle of motion is constantly changing.
Therefore its velocity is changing.
The object moving in a circle is constantly
accelerating.
FERRIS WHEEL
Top: N= mg - (mv^2/r) CENTRIPETAL ACCELERATION
Bottom: N = (mv^2/r) + mg The acceleration of an object moving in a
circle points toward the center of the circle.
CONICAL PENDULUM This is called a centripetal (center pointing)
acceleration.
g ⋅ tanθ = v^2/r
The centripetal acceleration depends on:
★ The speed of the object.
UNIFORM CIRCULAR MOTION ★ The radius of the circle.

The point or line that is the center of the circle is
the axis of rotation.
If the axis of rotation is inside the object, the
object is rotating (spinning).
If the axis of rotation is outside the object, the
object is revolving.

LINEAR/TANGENTIAL VELOCITY
CENTRIPETAL FORCE
Objects moving in a circle still have a linear
velocity = distance/time. Newton’s Second Law says that if an object is
This is often called tangential velocity, since the accelerating, there must be a net force on it.
direction of the linear velocity is tangent to the For an object moving in a circle, this is called the
circle. centripetal force.
The centripetal force points toward the center
ROTATIONAL/ANGULAR VELOCITY of the circle.
In order to make an object revolve about an axis,
Objects moving in a circle also have a rotational
the net force on the object must pull it toward
or angular velocity, which is the rate angular
the center of the circle.
position changes.
This force is called a centripetal (center-seeking)
Rotational velocity is measured in
force.
degrees/second, rotations/minute (rpm), etc.
Centripetal force on an object depends on:
Common symbol, ɷ (Greek letter omega)
★ The object’s mass - more mass means
Rotational velocity = change in angle/time
more force.
★ The object’s speed - more speed means
ROTATIONAL & LINEAR VELOCITY more force.
If an object is rotating: ★ The object’s distance from the axis
★ All points on the object have the same (radius).
rotational (angular) velocity.
★ All points on the object do not have the
same linear (tangential) velocity.
LEGAZPI CITY SCIENCE HIGHSCHOOL
9-CURIE
ADVANCE PHYSICS
Mrs. Analyn Fernandez

If linear velocity is held CONSERVATIVE FORCES
constant, more distance
requires less force. A force is conservative if the work it does on an
If rotational velocity is held object moving between two points is
constant, more distance independent of the path the objects take
requires more force. between the points.
The work depends only upon the initial and final
positions of the object
Any conservative force can have a potential
energy function associated with it
Work done by gravity
Work done by spring force

CENTRIFUGAL FORCE NONCONSERVATIVE FORCES
Centrifugal force” is a fictitious force - it is not
an interaction between 2 objects, and therefore A force is nonconservative if the work it does on
not a real force. an object depends on the path taken by the
Nothing pulls an object away from the center of object between its final and starting points.
the circle. The work depends upon the movement path
The term "centrifugal force" is often For a non-conservative force, potential energy
misattributed to an object's inertia, which refers can NOT be defined
to its desire to maintain its desired velocity. It is generally dissipative. The dispersal of
energy takes the form of heat or sound
Work done by a nonconservative force
BANKED CURVES

A banked curve is a curve that has its surface
at an angle with respect to the ground on
which the curve is positioned.
The reason for banking curves is to decrease the ENERGY
moving object's reliance on the force of friction.
ABILITY TO DO WORK
v = √rgtanθ
As you know, energy comes in many forms.
❖ Kinetic Energy
kulang to may notes nmn kayo ng formula bala kayo
❖ Potential Energy
diyan
❖ Gravitational Potential Energy (gravity)
❖ Elastic Potential Energy (springs, rubber
WORK AND ENERGY bands)
❖ Chemical Energy (chemical bonds)
TYPES OF FORCES ❖ Rest Mass Energy = Nuclear (E = mc2)
❖ Electric Potential Energy (ΔU = kq1q2/r)
❖ Thermal Energy (heat = KE of molecules)
CONSERVATIVE FORCES
❖ Sound (waves)
Work and energy associated with the force can ❖ Light (waves/photons)
be recovered
❖ Examples: Gravity, Spring Force, EM
forces
LAW OF CONSERVATION OF ENERGY
NONCONSERVATIVE FORCES
The forces are generally dissipative, and work “Energy can neither be created nor destroyed. It
done against it cannot easily be recovered can only be converted from one form of energy to
❖ Examples: Kinetic friction, air drag another. ”
forces, normal forces, tension forces,
applied forces
LEGAZPI CITY SCIENCE HIGHSCHOOL
9-CURIE
ADVANCE PHYSICS
Mrs. Analyn Fernandez

CONSERVED QUANTITIES
the change in the Kinetic Energy of the body.
Other conserved quantities that you may or may
not already be familiar with?

Conservation of mass.
Conservation of momentum.
POWER
Conservation of charge.
the rate at which work is done
CONSERVED OF ENERGY unit of power is watt (W)
1 W is energy transferred at the rate of one joule
The Law of Conservation of Energy simply states per second
that: P = w/t
❖ The energy of a system is constant. 1 000 w = 1kilowatt
❖ Energy cannot be created nor 1 hp = 750 watt
destroyed. P = energy transformed/ time taken
❖ Energy can only change form (e.g.
electrical to kinetic to potential, etc).
❖ True for any system with no external
forces.
❖ ET = KE + PE + Q (Constant)
❖ KE = Kinetic Energy
❖ PE = Potential Energy
❖ Q = Internal Energy [kinetic energy due
to the motion of molecules (translational,
rotational, vibrational)]

KINETIC ENERGY P = w/t T = w/P W = Pt
energy of motion
the energy an object possesses due to its motion.
The faster an object moves and the more
massive it is, the greater its kinetic energy.
KE = ½ mv^2 v=√2KE/m

POTENTIAL ENERGY
the stored energy an object has due to its
position or state.
energy of position
The two common types are gravitational
potential energy and elastic potential energy.
PE = mgh

MECHANICAL ENERGY
the sum of an object's kinetic energy and
potential energy.
In the absence of non-conservative forces like
friction, the total mechanical energy of a system
remains constant.

WORK-ENERGY THEOREM

The Work-Energy Theorem explains that the net
work done by all the forces acting on it is equal to