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Title: Physics GHSGT Review


1
Physics GHSGT Review
2
Speed and Velocity
  • Speed distance divided by time
  • s d/t
  • Units of speed m/s
  • Velocity speed in a given direction
  • Example
  • 55 mph speed
  • 55 mph north velocity

3
Distance versus Time Graph
  • AKA position versus time graph
  • Straight line represents constant (uniform) speed

4
Acceleration
  • Acceleration rate at which velocity changes
  • Involves a change in speed OR direction
  • a (vf vi )/ t
  • Units of acceleration m/s2
  • Example 0 to 60 mph in 5 seconds
  • For acceleration to occur a net (unbalanced)
    force must be applied

5
Distance versus Time Graph Revisited
  • Non-linear graph represents acceleration
  • Parabola constant acceleration

6
Forces
  • Force a push or a pull
  • Net Force sum of all forces acting on an object
  • Free-body diagram shows all forces with vector
    arrows
  • Direction of force direction of acceleration
  • Friction is a force that always opposes motion

7
Determining the Net Force
8
Newtons 1st Law of Motion
  • An object at rest will remain at rest and an
    object in constant motion will remain in constant
    motion unless acted on by an unbalanced force.
  • Reason for seatbelts

9
Newtons 2nd Law of Motion
  • Force mass x acceleration
  • F ma

10
Newtons 3rd Law of Motion
  • For every action, there is an equal but opposite
    reaction
  • Examples
  • Punch a wall, it punches back
  • Rocket propulsion

11
Gravity
  • Gravity attractive force between two objects
    that have mass
  • Depends on mass and distance

12
Effects of Mass and Distance on Gravity
13
Momentum
  • Momentum is mass in motion
  • p mv
  • To change an objects momentum a force must be
    applied
  • Conservation of momentum states that momentum
    before a collision equals momentum after

14
Energy and Work
  • The ability to do work
  • Work transfer of energy by applying a force to
    move an object
  • W Fd
  • where force and distance are in same direction
  • Both work and energy are measured in Joules

15
Examples of Work and No Work
  • Hammer applies a force to move the nail in the
    same direction WORK
  • Waiter applies a force upward while the tray
    moves forward NO WORK

16
Types of Mechanical Energy
  • Kinetic energy of motion
  • Potential stored energy due to position

17
Conservation of Energy
18
Conservation of Energy
19
Conversion of Energy
  • Motor converts electrical energy into
    mechanical energy
  • Motors make fans Move which is Mechanical
  • Generator converts mechanical energy into
    electrical energy
  • Georgia Power use a Generator to provide
    electricity

20
Power
  • Power rate at which work is done
  • P W/t
  • Measure in Watts
  • More work, less time More Power
  • Less Work, Long time Less Power

21
Heat Energy
  • Heat can be transferred through
  • Conduction when objects touch
  • Convection when matter moves
  • Radiation in the form of waves
  • Conductors easily transmit energy
  • Example metals
  • Insulators do not easily transmit energy
  • Example gases such as air

22
Light
  • Light is a form of electromagnetic radiation (EM)
  • EM spectrum shows the forms of radiation in order
    of increasing frequency and decreasing wavelength

23
Energy of a Wave
  • The energy transferred from a vibrating source is
    carried by a disturbance in the medium, not by
    matter moving from one place to another.
  • Waves move ENERGY, not matter
  • Energy carried by a wave consist of KE and PE

24
Parts of Wave
  • The dashed lines represent the equilibrium
  • The crests are the highest parts of the wave
    (letters A and F)
  • The troughs are the lowest parts of a wave
    (letters D and I)
  • Wavelength is the distance from crest to crest (A
    to F) or trough to trough (D to I)
  • Amplitude is the distance from the midpoint to
    the crest

Wavelength
crest
trough
Wavelength
25
Transverse Waves
  • Transverse wave a wave with a vibration at
    right angles to the direction the wave is
    traveling.
  • The energy moves through the medium left to
    right, but the motion of the wave is up and down
  • Makes an S shape wave
  • Ex light waves, string instrument

26
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27
Longitudinal Waves
  • Longitudinal wave a wave in which the vibration
    is in the same direction as that which the wave
    is traveling.
  • Both the energy motion and the movement of the
    wave are left to right
  • Makes a pulse through the wave
  • Ex sound waves, earthquake waves

28
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29
Doppler shift
  • The doppler shift a a change in frequency of a
    wave based on the movement of the observer or the
    source
  • Ex a siren changing pitch as it moves towards
    or away from you
  • http//www.colorado.edu/physics/2000/applets/doppl
    er2.html
  • http//www.colorado.edu/physics/2000/applets/doppl
    er.html

30
A Sound Wave
  • Sound waves are longitudinal waves.
  • Parts of a sound wave
  • 1) Compression areas of high pressure
  • 2) Rarefaction areas of low pressure
  • As a source vibrates in a periodic fashion, a
    series of compressions and rarefactions is
    produced
  • For all wave motion, it is not the medium that
    travels across the room, but a pulse (or energy)
    that travels.

31
  • The speed of sound varies in different media. In
    general, sound is transmitted faster in liquids
    than in gases, and still faster in solids.
  • Remember that sound DOES NOT travel through a
    vacuum

32
The EM Spectrum
  • All of the EM waves are the same in nature,
    differ only in the wavelength and frequency
  • Ronald McDonald Is Very Ugly X-tra Gross

33
  • The speed of light is constant when it travels
    through one type of medium.
  • Light travels faster in air than in water.
  • Molecules in its way slows light down
  • It is the opposite of sound waves, which require
    a medium to move faster
  • Light travels the fastest in a vacuum and slowest
    in a solid
  • The more molecules in its way, the slower it goes
  • Vacuum gt G gt L gt S

34
Color of Light
  • We see different colors depending on the
    frequency of light emitted or reflected
  • This is the reason blue flames are hotter than
    yellow. Blue has a higher frequency so more
    energy.

35
Mixing Colored Light
  • Light of all the visible frequencies mixed
    together produces white light.
  • White light can also be produced by mixing red,
    blue, and green light.
  • Red, blue, and green are the 3 primary colors of
    light.
  • Color T.V.s produce all the colors we perceive by
    combining red, blue, and green light in a variety
    of ways.

36
Adding Primary Colors
  • Red Green Yellow
  • Red Blue Magenta (Purple)
  • Blue Green Cyan (Aqua)
  • Red Blue Green White

37
Refraction of Light
  • Light waves travel faster in air than in water
    and slower in glass than water.
  • More dense slower light
  • When light enters a different medium, speed
    changes and it bends.
  • Bending of light due to change in speed
    REFRACTION

38
Electricity
  • Electrons carry a negative charge.
  • Lost electrons positive charge
  • Gained electrons negative charge
  • REMEMBER
  • Like charges repel
  • Opposites attract
  • An object can be charged through
  • Friction (rubbing two objects together)
  • Conduction (touching a charged object to an
    uncharged object)
  • Induction (holding a charged object near an
    uncharged object)

39
Electrical Circuits
SERIES
  • Current flows in a closed circuit
  • Ohms Law
  • V IR
  • Two types of circuits
  • Series (single path)
  • Parallel (poly paths)

PARALLEL
40
Electromagnet
  • One can make an electromagnet with a nail,
    battery, and wire
  • When current flows through the coiled wire, the
    nail becomes magnetized.

41
Electromagnetic Induction
  • Occurs when a current is produced by moving a
    conducting wire through a magnetic field

42
Radioactive Half-Life
  • Half-life The time required for half of the
    atoms of a radioactive isotope of an element to
    decay.
  • Radioactive isotopes decay at different rates
  • The amount of a substance halves every half-life
  • Ex If the half life of an isotope if 10 years,
    then after 10 years there is only half left.
    After 20 years, there is only half of that half
    (or 1/4th left)
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