Science FCAT Benchmark Review

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Title: Science FCAT Benchmark Review

1
Science FCATBenchmark Review
2
Strand A The Nature of Matter

What is matter?
Anything that has mass and takes up space.
Density the amount of matter in a given volume
(DM/V)
Ductility the ability to be pulled into a thin
strand, like a wire
Malleability the ability to be pressed or
pounded into a thin sheet

3
These are examples of?
4
Formula for Density

D M/V
Where
DDensity
MMass
VVolume

5
Strand A The Nature of Matter

Electrical Conductivity How well a substance
allows electricity to flow through it
Solubility The ability to dissolve in another
substance

6
Strand A The Nature of Matter

Physical Properties
Are those that can be observed without changing
the make-up, or identity of the matter.
Chemical Properties
Describe matter based on its ability to change
into a new kind of matter. Ie, paper/flammability,
iron/O2

7
Strand A The Nature of Matter

Physical Change occurs when a physical property
(size/shape) of a substance is changed many
physical changes can be undone. Ie, folding paper
Chemical Change occurs when a one or more
substances are changed into new substances with
different properties cannot be undone by
physical means

8
Strand A The Nature of Matter
9
Strand A The Nature of Matter

Defining Features
Solid
Keeps it shape and volume
Liquid
Takes the shape of its container
Keeps the same volume, in a container or not
Can flow
Gas
Takes the shape of its?
Takes the volume of ?
Can ?

10
Strand A The Nature of Matter

Boiling Point temperature at which a substance
changes from a liquid state to a gaseous state
Freezing Point temperature at which a substance
changes from a liquid state to a solid state
Melting Point temperature at which a substance
changes from a solid state to a liquid state
Condensation Point temperature at which a
substance changes from a gaseous state to a
liquid state
Sublimation change from the solid state to the
gaseous state
Deposition change from the gaseous state to the
solid state

11
Strand A The Nature of Matter

Temperature measure of the average kinetic
energy of the particles of a substance. Scales
used?

12
Strand A The Nature of Matter

Waves
Crest peak/highest point of wave
Trough valley/lowest point of wave
Amplitude distance the wave oscillates from its
resting position. The larger the amplitude, the
more energy carried by the wave.
Wavelength the distance from one point on one
wave to a corresponding point on an adjacent
wave, ie. crest to crest, rp to rp, trough to
trough
Resting Position

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14

http//id.mind.net/zona/mstm/physics/waves/partsO
fAWave/waveParts.htm

15
Strand A The Nature of Matter

Element simplest form of matter
Atom smallest particle into which an element
can be divided and still have properties of that
element.
Compound/Molecule Two or more elements that are
combined.
Mixture a combination of two or more substances
that have not combined chemically

16
Strand A The Nature of Matter

Subatomic Particles
Proton positive charge nucleus
Neutron no charge nucleus
Electron negative charge outside the nucleus
(electron clouds)
Proton and neutrons have about the same mass.
Electrons are significantly smaller.
An atom is identified by the number of protons in
its nucleus

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Strand A The Nature of Matter

Isotopes Isotopes are atoms of the same element
that have a different number of neutrons.
Hydrogen has one proton.
0 neutron protium
1 neutron deuterium
2 neutrons tritium

19
A. Mixture
B. Solution
C. Compound
D. Pure Substance
20
You are correct!
Why are B, C and D not correct?
21
Strand B - Energy

Energy the ability to do work
Geothermal energy obtained from the thermal
energy inside Earth
Mechanical energy an object has because of its
motion or position (kinetic/potential)
Nuclear energy contained in the nuclei of atoms

22
What kinds of power plants are these?
23
Strand B - Energy

Wind using the wind (turbines)
Hydroelectric using water
Tidal using the waves/tides
Solar using sun (photovoltaic cells)
Fossil fuels oil, coal, natural gas (formed
millions of years ago).
Electrical energy produced by electric charges

Turbines, turbines, turbines!!!!
Remember that most power plants have a turbine
somewhere in them that allows them to convert
(not create) energy.
Remember that energy can never be created or
destroyed.

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What kinds of power plants are these?
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29
Strand B - Energy

Sound energy carried by sound waves
Light energy carried by light and other kinds
of electromagnetic waves
Chemical energy stored in chemical bonds
Thermal Energy related to the temperature of a
substance
Conduction, Convection, Radiation

30
Strand B - Energy

Conduction transfer of heat from a warmer
substance to a cooler substance (contact)
Convection transfer of heat warmer fluid/gas
rises and cooler sinks
Radiation transfer of heat in the form of
electromagnetic waves at random

31
Conduction
Convection
Radiation
32
Strand B Energy

Law of Conservation of Energy Energy cannot be
created nor destroyed, it can only change form or
be transferred
Kinetic Energy energy an object has in motion
Potential Energy stored energy an object has

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Strand B - Energy

Energy from Sun (electromagnetic spectrum)
Energy inefficiency (heat loss) ie, lamp example
Heat flow ? warmer to cooler
Energy flow sun ? plants ? animals ? fossil
fuels ? heat

35
Benchmarks SC.B.1.2.2, SC.B.1.2.3,
SC.B.1.2.4, SC.B.1.2.5 and SC.B.1.2.6
F. Electrical
G. Heat
H. Light
I. Mechanical
36
You are correct!
Why are G, H and I not correct?
37
Strand C Force and Motion

Force push or pull

38
Scalars Vectors

The motion of objects can be described by words -
words such as distance, displacement, speed,
velocity, and acceleration. These mathematical
quantities which are used to describe the motion
of objects can be divided into two categories.
The quantity is either a scalar or a vector.
These two categories can be distinguished from
one another by their distinct definitions
Scalars are quantities which are fully described
by a magnitude alone.
Vectors are quantities which are fully described
by both a magnitude and a direction.

39
Scalars Vectors

Distance and speed are scalar quantities
Displacement and velocity are vector quantities.
Examples While speed (like 30km/hr) is a scalar,
velocity (30km/hr North) is a vector, consisting
of a speed and a direction (north).

40
Scalar or Vector?

5 m
30 m/sec, East
20 degrees Celsius
256 bytes
4,000 calories
5 mi., right

41
Distance/Displacement

Distance and displacement are two quantities
which may seem to mean the same thing, yet they
have distinctly different meanings and
definitions.
Distance is a scalar quantity which refers to
"how much ground an object has covered" during
its motion.
Displacement is a vector quantity which refers to
"how far out of place an object is" it is the
object's change in position.

42
Distance/Displacement Check

A student walks 4 meters East, 2 meters South, 4
meters West, and finally 2 meters North.

4 meters 2 meters 2 meters 4
meters
43
Distance/Displacement

Even though the student has walked a total
distance of 12 meters, her displacement is 0
meters. During the course of her motion, she has
"covered 12 meters of ground" (distance 12 m).
Yet, when she is finished walking, she is not
"out of place" i.e., there is no displacement
for her motion (displacement 0 m).
Displacement, being a vector quantity, must give
attention to direction. The 4 meters east is
canceled by the 4 meters west and the 2 meters
south is canceled by the 2 meters north.

44
Distance/Displacement Check

The diagram below shows the position of a
cross-country skier at various times. At each of
the indicated times, the skier turns around and
reverses the direction of travel. In other words,
the skier moves from A to B to C to D. Use the
diagram to determine the distance traveled by the
skier and the resulting displacement during these
three minutes.
A B
40 m 40 m___
100 m
C D

45
Distance/Displacement

Seymour Action views soccer games from under the
bleachers. He frequently paces back and forth to
get the best view. The following diagram below
shows several of Seymour's positions at various
times. At each marked position, Seymour makes a
"U-turn" and moves in the opposite direction. In
other words, Seymour moves from position A to B
to C to D. What is Seymour's resulting
displacement and distance of travel?

46
Distance/Displacement

D B C A
___________________________________
-10 0 10 20 30

47
Lets Check

What is the displacement of a cross country team
that begins a ten mile course ending up back at
the school?
What is the distance and displacement of the race
car drivers in the Indy 500?

48
Speed

Speed is a scalar quantity which refers to "how
fast an object is moving." A fast-moving object
has a high speed while a slow-moving object has a
low speed. An object with no movement at all has
a zero speed.

49
Constant Speed

Moving objects don't always travel with erratic
and changing speeds. Occasionally, an object will
move at a steady rate with a constant speed. That
is, the object will cover the same distance every
regular interval of time. For instance, a
cross-country runner might be running with a
constant speed of 6 m/s in a straight line. If
her speed is constant, then the distance traveled
every second is the same. The runner would cover
a distance of 6 meters every second. If you
measured her position each second, you would
notice that her position was changing by 6 meters
each second. The following data tables depict
both constant and changing speeds

50
Constant Speed
Time (s) Position (m)
0 0
1 6
2 12
3 18
4 24
51
Changing Speed
Time (s) Position (m)
0 0
1 1
2 4
3 9
4 16
52
Instantaneous Speed

Since a moving object often changes its speed
during its motion, it is common to distinguish
between the average speed and the instantaneous
speed. The distinction is as follows
Instantaneous Speed - speed at any given instant
in time.
Average Speed - average of all instantaneous
speeds found simply by a distance/time ratio.

53
Instantaneous Speed

You might think of the instantaneous speed as the
speed which the speedometer reads at any given
instant in time and the average speed as the
average of all the speedometer readings during
the course of the trip.

54
Average Speed

As an object moves, it often undergoes changes in
speed. For example, during an average trip to
school, there are many changes in speed. Rather
than the speedometer maintaining a steady
reading, the needle constantly moves up and down
to reflect the stopping and starting and the
accelerating and decelerating. At one instant,
the car may be moving at 50 mi/hr and at another
instant, it may be stopped (i.e., 0 mi/hr). Yet
during the course of the trip to school the
person might average a speed of 25 mi/hr.

55
Average Speed

The instantaneous speed of an object is not to be
confused with the average speed. Average speed is
a measure of the distance traveled in a given
period of time. Suppose that during your trip to
school, you traveled a distance of 5 miles and
the trip lasted 0.2 hours (12 minutes). The
average speed of your car could be determined as

56
Average Speed

Average Speed Distance/Time
Average Speed 5 miles/.2 hour
Average Speed 25 miles/hour
On the average, your car was moving with a speed
of 25 miles per hour. During your trip, there may
have been times that you were stopped and other
times that your speedometer was reading 50 miles
per hour yet on the average you were moving with
a speed of 25 miles per hour.

57
Average Speed Check

While on vacation, Lisa Carr traveled a total
distance of 400 miles. Her trip took 8 hours.
What was her average speed? To compute her
average speed, simply divide the distance of
travel by the time of travel.
Lisa Carr averaged a speed of 50 miles per hour.
She may not have been traveling at a constant
speed of 50 mi/hr. She undoubtedly, was stopped
at some instant in time (perhaps for a bathroom
break or for lunch) and she probably was going 65
mi/hr at other instants in time. Yet, she
averaged a speed of 50 miles per hour.

58
Velocity

Velocity is a vector quantity which refers to
"the rate at which an object changes its
position."
Imagine a person moving one step forward and one
step back. Because the person always returns to
the original position, the motion would never
result in a change in position. Since velocity is
defined as the rate at which the position
changes, this motion results in zero velocity.
If a person in motion wishes to maximize his/her
velocity, then that person must make every effort
to maximize the amount that he/she is displaced
from his/her original position. Every step must
go into moving that person further from where
he/she started. Heading in the opposite direction
effectively begins to cancel whatever
displacement there once was.

59
Describing Velocity

The task of describing the direction of the
velocity vector is easy! The direction of the
velocity vector is the same as the direction in
which an object is moving. It does not matter
whether the object is speeding up or slowing
down, if the object is moving rightwards, then
its velocity is described as being rightwards. If
an object is moving downwards, then its velocity
is described as being downwards. Thus an airplane
moving towards the west with a speed of 300 mi/hr
has a velocity of 300 mi/hr, west. Note that
speed has no direction (it is a scalar) and that
velocity is simply the speed with a direction.

60
Terminal Velocity

The terminal velocity of an object falling toward
the earth, in non-vacuum, is the speed at which
the gravitational force is pulling downwards and
an opposing force is faced by the resistance of
air (resistance) pushing upwards. 9.8 m/s2

61
Acceleration

Acceleration is a vector quantity which is
defined as "the rate at which an object changes
its velocity." An object is accelerating if it is
changing its velocity.
Sports announcers will occasionally say that a
person is accelerating if he/she is moving fast.
Yet acceleration has nothing to do with going
fast. A person can be moving very fast, and still
not be accelerating. Acceleration has to do with
changing how fast an object is moving. If an
object is not changing its velocity, then the
object is not accelerating.

62
Strand C Force and Motion

Non-contact forces magnetism/gravity
Weight v. Mass
Series Circuit connecting a circuit in a line
Parallel Circuit divide the current among
different devices

63
Which is parallel? Which is series?
64
Force

A force is a push or pull. If an object
accelerates (speeds up, slows down, or turns), a
force is acting upon it.
The total force felt by an object is called the
net force.
Some force are not visible (i.e. gravity,
magnetism or earths gravitational field).

65
Forces

Balanced forces are two or more forces that
cancel out each others effects and do not cause a
change in motion. Net force equals zero.
Unbalanced forces exceed zero and therefore cause
motion.

66
Newtons First Law of Motion

Also know as Newtons law of inertia.
An object will remain at rest or move with
constant velocity until it is acted upon by a net
force
Difficult to prove because of friction.

67
Friction

The unbalanced force that brings nearly
everything to a stop.
The smoother the surface, the ?
Static friction prevents an object from moving
when force is applied (i.e. pushing something
heavy or walking).
Sliding friction slows an object that can slide
(i.e. skidding tires, shuffling shoes).

68
Friction

Rolling friction needed to make a wheel turn.
Rolling friction pushes back so that a tire can
roll forward.
Air resistance acts against the direction of
motion and gets stronger as an object goes faster.

69
Newtons Second Law of Motion

An object acted upon by a net force will
accelerate in the direction of the force
according to the following equation
Acceleration net force/mass
a F net/m or F net ma
Force is measured in Newtons (N)
1 N 1 kg . m/s2

70
Newtons Third Law

For every action, there is an equal and opposite
reaction.
While driving down the road, an unfortunate bug
strikes the windshield of a bug. Quite obviously,
this is a case of Newton's third law of motion.
The bug hit the bus and the windshield hit the
bus. Which of the two forces is greater the
force on the bug or the force on the bus?

Rockets are unable to accelerate in space because
...
a. there is no air in space for the rockets to
push off of.
b. there is no gravity is in space.
c. there is no air resistance in space.
d. ... nonsense! Rockets do accelerate in space.

72
A. Earths Shape
B. Earths Gravity
C. Earths Mountains
D. Earths Atmosphere
73
You are Correct!
Why are A, B, and C not correct?
74
Benchmarks SC.C.2.2.4, SC.C.2.2.2, SC.C.2.2.3
F. Ice Block
H. Sand Block
G. Sponge Block
I. Plastic Block
75
You are Correct!
Why are G, H and I not correct?
76
Strand D Processes that Shape the Earth

Igneous Rocks formed when magma or lava cools
and becomes solid.
Sedimentary formed when sediment is pressed and
cemented
Metamorphic formed when rock have been changed
over time with high pressure and temperature

77
Strand D Processes that Shape the Earth

Melting hot temperatures deep inside Earth melt
rocks, forming magma
Cooling and Hardening Magma that rises from
deep inside earth cools and hardens into rock
(both above/below surface).
Weathering and Erosion breaks apart existing
rocks, forming sediment. Erosion moves sediment.
Compacting and Cementing Pressure compacts
water between particles evaporates.
Heat and Pressure melt and squeeze minerals
changing the minerals or grain size.

78
Rock Cycle
79
Weathering Processes

Mechanical Weathering process whereby rock
physically break down into smaller pieces but do
not change chemical composition.
Chemical Weathering process whereby rock is
broken down and chemical composition changes.

80
Agents of Mechanical Weathering

Ice Wedging water seeps into cracks or joints
in rocks and freeze.
Organic Activity Roots of plants and animals
burrowing.
Abrasion collision of rocks with one another
because of gravity, running water, or wind

81
Agents of Chemical Weathering

Hydrolysis minerals chemically reacting with
water. Minerals affected may be transported by
water causing leaching.
Carbonation minerals chemically reacting with
carbonic acid (CO2 H2O)
Stalactites on ceiling holding tight (tite)
Stalagmites on ground might make it up

82
Agents of Chemical Weathering

Oxidation metallic minerals chemically reacting
with oxygen causing oxidation.
Acid Precipitation CO2 precipitation
Plant acids weak acids produced by plants

83
Rates of Weathering

Rock Composition Quartz is least affected
limestone is most affected.
Amount of Exposure the more exposure the faster
it will weather
Climate Climates with much rainfall and
freezing contribute most. Very hot or very cold
little weathering. Moist/humid much weathering.
Topography temperature/slope

84
Continental Drift

Theory stating that continents moved.
Proposed by Alfred Wegener.
Evidence included
Identical fossil remains on the coast of South
America and Africa
Age and type of rock on the coastline
Appalachian mountain chain
Glacier debris in Africa and South America

85
Pangaea
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87
Seafloor Spreading

Suggested by Harry Hess.
A break or rift in the earths crust allowing
magma to go out.
Ocean floor Paleomagnetism

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89
Plate tectonics

Combines continental drift and seafloor spreading
not only describes continental movement but
proposes an explanation on why it moves.
Two types of earths crust.
Oceanic makes up the ocean floor.
Continental makes up the continental landmasses.

90
Lithospheric Plates
91
Lithospheric Plates

Lithosphere the rigid upper mantle of the
earths crust.
Divergent Boundary Plate moving apart.
Convergent Boundary Plates moving toward each
other.
Subduction Zone
Plate density
Transform fault boundary Plate grind past each
other.

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95
Convection Cells
This is the major theory on how lithospheric
plates move. In which direction is heat flowing?
96
Earthquakes

Caused by transform plate boundary movement.
Aftershocks
Focus is where the earthquake begins.
Epicenter is the place directly above the focus.

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98
Seismic Waves

Primary waves or P waves fastest and first to
be recorded on a seismograph.
Secondary waves or S waves second to be
recorded on a seismograph.
Surface waves or L waves slowest moving waves
and last to be recorded.

99
Locating an Earthquake
100
Earthquake Measurement

Richter scale measures the amount of energy
released by an earthquake.
Largest recorded was 9.6
Mercalli scale measures the amount of damage an
earthquake causes.
Measured by Roman numerals I - XII

101
Tsunamis

A giant ocean wave usually caused by a major
earthquake with its epicenter on the ocean floor.

102
Earthquake Safety

Before an earthquake, be prepared.
During an earthquake, stay calm.
After an earthquake, be cautious.

103
Volcanism

Any activity that includes the movement of magma
toward or onto the surface of the earth.
Magma versus lava.
Vent opening through
which molten rock flows.
Volcano vent and
volcanic material.

104
Pacific Ring of Fire
105
Hotspots
106
Volcanic Cones

Shield Cones broad, gentle sloping
Cinder Cones steep slopes caused by explosive
eruptions
Composite or stratovolcano features of both

107
Shield Cones
108
Meteorology

Meteorology is the study of the atmosphere.
The atmosphere is a layer of gases and particles
that surround the earth.
Influences almost every living thing.
Weather is the general condition of the
atmosphere at a particular place and time.
Climate is the general weather condition over
many years.

109
Composition of Atmosphere

The most abundant elements in the air are the
gases nitrogen (75), oxygen (24) and argon
(1).
The most abundant compounds in the air are the
gases carbon dioxide (CO2) and water vapor (H2O).
Ozone (O3) is found in the upper atmosphere. It
absorbs harmful ultraviolet rays from the sun.

110
Atmospheric Pressure

Gravity pulls the gases of the atmosphere toward
the earths surface and holds them there.
The ratio of the weight of the air to the area of
the surface on which it presses is called
atmospheric pressure.
Since there is less air at higher altitudes,
there is less weight pressing down. This explains
why there is lower atmospheric pressure at higher
altitudes.

111
Barometer

A barometer is an instrument that measures
atmospheric pressure. Two types mercurial and
aneroid. Miami averages 30 inches of Hg.

112
Layers of the Atmosphere

Four basic layers.
Troposphere closest to the earth. Nearly all
weather changes occur here.
Stratosphere second layer from the earth. Most
of the ozone is found here.
Mesosphere known for its significant
temperature drop.
Thermosphere Last layer. Very thin air.

113
Air Pollution

Any substance in the atmosphere that is harmful
to people, animals, plants or property is an air
pollutant.
Main source is the burning of fossil fuels.
Gases emitted by the burning of fossil fuels form
acids when combined with water in the air Acid
Precipitation.
International and federal intervention is needed.

114
Solar Energy

All the energy the earth receives from the sun
travels through space between the earth and the
sun as radiation.
Light is a form of radiation we can however,
there are many other forms that cannot be seen.
The waves that make up all forms of radiation are
called electromagnetic waves.

115
Electromagnetic Spectrum
116
Electromagnetic Spectrum
117
Scattering

Water and dust suspended in the atmosphere
reflect and bend the suns rays. As a result,
sunlight comes from all directions.
Short wavelengths (blue) are easier to scatter
making the sky blue.
Long wavelengths (red) are last to be scattered
making the sun red at dawn/dusk.

118
Reflection

Of the total amount of solar energy reaching the
earths atmosphere, about 20 is absorbed by the
atmosphere.
About 30 is scattered back into space or
reflected by the clouds or surface.
About 50 is absorbed by the surface.
The different surfaces on earth vary their
absorption and reflection rate.

119
The Greenhouse Effect

Gas molecules in the atmosphere trap heat energy
and prevent it from escaping back into space. As
a result the lower atmosphere becomes warm.
Essentially, rays come in but cant get out.
Similar to a vehicle on a hot day.

120
The Greenhouse Effect
121
Conduction and Convection

Not all heating of the atmosphere comes from
radiation.
Conduction has particle to particle contact.
Convection involves the movement of gases or
liquids when they are heated unevenly.
Cooler air sinks.
Warmer air rises.

122
Winds

More solar energy at equator cause a belt of low
pressure.
The poles have colder, heavier air that tends to
sink.
Pressure differences in the atmosphere at the
equator and at the poles create a general
movement of air worldwide.

123
Winds
124
Breezes

Gentle winds that extend over distances of less
than 100 km are called breezes.
Land surfaces heat up faster and cool more
rapidly than water surfaces do.
During the day, warm air above the land rises and
the cool air above the water moves in to replace
it.
During the night, vice versa.

125
Atmospheric Moisture

The amount of water vapor in the atmosphere is
known as humidity.
When the air holds all the water vapor it can, it
is said to be saturated.
The higher the temperature, the more water vapor
it can hold.
Relative Humidity compares the mass of water
vapor in the air with the amount of water vapor
the air can hold at that temperature.

126
Atmospheric Moisture

A psychrometer, hair hygrometer or electric
hygrometer are instruments used to measure
relative humidity.
Specific humidity refers to the actual amount of
water vapor in the air.
The temperature to which air must be cooled to
reach saturation is dew point. Any temperature
below dew point will cause dew.
If the dew point is below the freezing
temperature of water, water vapor will change
directly into solid ice crystals, or frost.

127
Dew and frost.
Remember condensation and deposition?
128
Clouds and Fog

Clouds and fog are visible masses of tiny water
or ice particles suspended in the atmosphere.
Both originate from water vapor in the air.
Not all clouds cause rain.
Fog generally forms near the surface of the earth
when air close to the ground is cooled.

129
Clouds
130
Fog
131
Precipitation

Any moisture that falls from the air to earths
surface is called precipitation.
Rain is liquid precipitation. Measured with rain
gauge.
Drizzle if lt .5 mm in diameter.
Snow is the most common form of solid
precipitation.
Sleet is ice pellets that form when rain falls
through a layer of freezing air.
Hail is lumps of ice. Can be spherical or
irregular.

132
Air Masses

A large body of air with uniform temperature and
moisture content is called an air mass.
Air masses over polar regions are usually very
cold and dry.
Air masses over tropical regions are usually warm
and moist.
Air masses are classified according to their
source region.

133
Fronts

When two unlike air masses meet, density
differences usually keep the two air masses
separate.
The boundary that forms between the two air
masses is called a front.
The kind of front that forms depends on how the
air masses are moving.

134
Types of Fronts

Cold front when a cold air mass overtakes a
warm air mass.
A long line of thunderstorms, called a squall
line, may occur just ahead of a fast moving cold
front.
Warm front when a warm air mass overtakes a
cooler air mass.
Stationary front when two air masses meet and
neither is displaced.
Occluded front when a fast moving cold front
overtakes a warm front, lifting the warm air
completely off the ground.

135
Cyclones

A severe tropical storm, with windspeeds starting
at 120km/hr is called a hurricane.
In the North Pacific they are called typhoons.
A storm accompanied by thunder, lightning and
strong winds is called a thunderstorm.
A tornado is a whirling, funnel shaped cyclone.
Tornadoes over the ocean are called waterspouts.

136
Weather Instruments

Thermometer measure temperature.
Anemometer measures wind speed.
Wind vane determines wind direction.
Radiosonde instrument package to investigate
weather conditions in the upper atmosphere.
Radar uses radio waves to detect precipitation
and storms.
Supercomputers store weather data, interpret
data, and forecast.

137
A. Sandy flatlands
C. Underground caves
B. Offshore islands
D. Mangrove swamps
138
Congratulations,
You are correct!
Why are A, B and D not correct?
139
Which of the following did NOT cause the
formation of the Grand Canyon
F. Weathering
H. Water
G. Lava
I. Wind Erosion
140
You are correct!
141
Strand E Earth and Space

Tides daily rise and fall of the oceans caused
mainly by the moon
Neap least extreme (happen twice a month)
Spring most extreme (happen ?)

142
Astronomy is

The study of the universe beyond earth
One of the oldest branches of science
Ancient Babylonians charted the positions of
planets and stars 4,000 years ago.
Modern astronomers use telescopes and other
instruments.

143
Stars

A star is a body of gases that gives off a
tremendous amount of energy in the form of light
and heat.
Stars can vary in size, shape, and color.
Distances between the stars and earth are
measured in light-years a light year is the
distance that light travels in one year.

144
Star Brightness

Apparent Magnitude the brightness of a star as
it appears from the earth
Absolute Magnitude the true brightness of a
star how bright the star would appear if it was
seen from a distance of 32.6 light-years

145
Hertzsprung-Russell Diagram

The H-R Diagram graphs the surface temperatures
of stars against their absolute magnitudes
Most stars are called Main-Sequence Stars,
including the sun and other stars in the night
sky
Cool, large, bright stars are Giants or
Supergiants
Hot, small, dim stars are White Dwarfs

146
Hertzsprung-Russell Diagram
What scale is used here?
147
A Star is Born

A star begins as a nebula, a cloud of gas and
dust.
The particles of gas and dust come together, and
the nebula shrinks in size and begins to spin.
The shrinking, spinning nebula flattens into a
disk of matter called a protostar.
When nuclear fusion occurs, a prostar begins to
generate energy and is classified as a star.

148
The Life of a Star

1st Stage Nebula Protostar Star
2nd Stage Main Sequence Star
3rd Stage Giant/Supergiant
4th Stage White Dwarf
5th Stage Black Dwarf
No Black Dwarfs exist yet

149
Star Terms

A white dwarf which explodes, releasing energy,
gas, and dust is a nova.
A star that has tremendous energy and blows
itself apart is called a supernova.
A hole in space with gravity so great that not
even light can escape is called a black hole. It
is caused by the collapse of a large supernova.

150
Constellations

Constellations are star patterns that occur in
shifting, but fixed patterns.
Constellations have been used to locate other
stars in the sky or to guide travelers.
Astronomers recognize 88 constellations
Many are named after mythical creatures.

151
Constellations
152
Galaxies

Galaxies are large-scale groups of stars bound
together by gravitational attraction.
Spiral Galaxies
Elliptical Galaxies
Irregular Galaxies
The Sun is a star in the Milky Way Galaxy, a
Spiral Galaxy.

153
Spiral Galaxy
154
Elliptical Galaxy
155
Irregular Galaxy
156
The Sun

The center of the sun is the core and, like the
rest of the sun, is made entirely of gas.
The process of nuclear fusion, which creates the
suns energy, occurs in the core.
The core is surrounded by the radiative zone and
the convective zone.

157
The Suns Atmosphere

The photosphere (light sphere) is the innermost
layer of the atmosphere and is often considered
the surface of the sun.
The chromosphere, or color sphere, appears to
glow with a reddish light.
The corona, the outermost layer of the
atmosphere, prevents the atomic particles from
the surface from escaping into space.

158
The Suns Composition
159
Solar Activity

Sunspots are cool, dark areas of gas within the
photosphere that are caused by powerful magnetic
fields.
Prominences are clouds of glowing gases which
form huge arches reaching above the suns surface.

160
Solar Activity, cont.

Solar flares are sudden outward eruptions of
electrically charged atomic particles.
Auroras are bands of light that appear in the sky
after magnetic storms.

161
The Solar System

Includes the sun and the bodies revolving around
the sun.
There are 9 major bodies, or planets, that orbit
the sun.
Copernicus suggested a heliocentric, or
sun-centered universe, in the 1500s. Before, most
people believed that the sun, planets, and
stars orbited around the earth.

162
The Inner Planets

Mercury, Venus, Earth, and Mars are the four
planets closest to the sun and are known as the
Inner, or Terrestrial, planets.
All of these planets consist mostly of solid
rock, with a metal core. These planets have no
rings and a maximum of two moons.
The inner planets have impact craters, which
resulted from the collisions of the planets with
objects made of rock.

163
Mercury

Planet closest to sun
Does not have any moons
Probably has not changed much since the creation
of the solar system
Has a thin atmosphere because it is so close to
the sun and so small
Huge temperature range (-173C - 427C)

164
Venus

Second planet from the sun
Sometimes called the earths twin they are
almost the same size, mass, and density.
Average surface temperature is 435C too hot to
support life
May have been oceans and volcanoes on Venus
Atmosphere is 96 CO2

165
Earth

Fifth largest planet
Has one moon
Active Geologic History
Only planet with known life
Only planet with oceans abundant H2O
Average surface temperature is 14C

166
Mars

Has 2 moons
Has similar rotation and seasons as the Earth
Geologically Active Volcanic Activity
Astronomers believe that Mars once had a warmer
wetter climate

167
The Outer Planets

Jupiter, Saturn, Uranus, and Neptune are called
the giant planets and are some of the largest in
the solar system.
Called the Jovian Planets
Larger and more massive than the other planets,
but they are far less dense
Have thick atmosphere made of H2 and He gases
Core of rock, metal, and H2O

168
Jupiter

Largest planet in the solar system
At least 16 moons and 1 ring
Liquid metallic core
Mostly made of gases
Surface is marked by light- and dark-colored
bands
Great Red Spot giant rotating storm that has
been raging for several hundred years

169
Saturn

Has at least 20 moons and several rings
Spins rapidly
Has bands of colored clouds
Less dense than Jupiter
Has a very complex system of rings

170
Uranus

Has at least 15 moons and 11 rings
Unusual Rotation rotates like a rolling ball
Greenish color indicates that atmosphere contains
methane
A core of rock and metals is at the
center of this planet

171
Neptune

Has 8 moons and possibly 4 rings
Atmosphere made of helium, hydrogen, and methane
Very active weather system
Great Dark Spot An earth-sized storm is always
visible in Neptunes atmosphere

172
Pluto

Accidental Discovery
No longer considered a planet Orbits sun in
unusually elongated ellipse
Made mostly of frozen methane, rock, and ice
One moon Charon which is half as large as
Pluto
Pluto could have once been a moon of Neptune,
based on its size, unusual orbit, and large moon.

173
Order of the Planets
174
Asteroids, Comets, Meteoroids

Asteroids are fragments of rock that
orbit the sun.
A comet is a body of ice, rock, dust,
methane, and ammonia which orbits
the sun in a long ellipse.
A meteoroid is a small bit of rock or metal that
moves through the solar system
A meteor is a meteoroid that enters the earths
atmosphere.
A meteorite is any part of a meteor that remains
after it hits the earths surface.

175
Halleys Comet

A short-period comet that last appeared in 1986.
It will reappear in 2062.

176
The Moon

A body that orbits a larger body is called a
satellite.
The moon is a natural satellite of the earth.
The moons gravity is 1/6 less that on earth.
The moon has no atmosphere and cannot support
life.
6 Apollo Spacecraft have visited the moon.
Temperature ranges from 170C to 134C.

177
Lunar Surface

Highlands of light-colored rock.
Dark areas of solidified lava are called maria
they are the remains of volcanic eruptions.
Long, deep channels called rilles run through the
maria.

178
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179
Craters

Craters are bowl-shaped depressions found on the
surface of the moon. They were most likely
created from debris that struck the moon.

180
Eclipses

An eclipse occurs when one planetary body passes
through the shadow of another.
When the moon is between the earth and the sun,
the shadow of the moon may fall upon the earth,
causing a solar eclipse.
A lunar eclipse occurs when then earth is
positioned between the moon and the sun, and the
earths shadow crosses the lighted half of the
moon.

181
Strand E Earth and Space

Solar Eclipse
When moon passes between Earth and sun

182
Strand E Earth and Space

Lunar Eclipse
When Earth passes between sun and moon

183
Solar Eclipse
184
Lunar Eclipse
185
The Lunar Cycle

For much of history, people were able to measure
the passing of time by keeping track of the
changing phases of the moon.
Eventually, calendars were created to track the
passing of time.

186
Days, Months, Years

A day is the time required for the earth to make
one rotation on its axis 24 hours.
A lunar month is the time required for the moon
to go through one cycle of phases as it orbits
the earth 29.5 days.
A solar year is the time required for the earth
to make one orbit around the sun 365.24 days.

187
How do we get our seasons?
188
Strand E Earth and Space

Satellite object that revolves around a larger
object in space
Moons are natural satellites
Artificial satellites serve technological
purposes
Difference between probe and satellite?

189
F The shape of the orbit
G The closeness of Mars
H The presence of a moon
I The distance from the Sun
190
You are correct!
Why are F, G and H not correct?
191
Strand F Processes of Life

Biology is the scientific study of living things.
There are more than 2 million species of living
things on the earth. They range in size from
microscopic bacteria to huge blue whales and
towering redwood trees.
Living things also differ greatly in where and
how they live.

192
Processes of Living Things

Characteristics include made up of cells,
reproduce, grow, obtain and use energy, and
respond to the environment.
Other characteristics may include need water,
composed of many chemical substances and are
highly organized, have a definite structure and
size, have a definite life-span, show adaptation,
evolve, or change, over long periods of time.

193
Levels of Organization

Levels of organization
Subatomic Particles -gt Atoms -gt Molecules -gt
Cells -gt Tissues -gt Organs -gt Organ Systems -gt
Organism -gt Population -gt Community -gt Ecosystem
(Biome) -gt Biosphere

194
Levels of Organization

Population the simplest grouping of organisms
in nature (all the frogs in a pond).
Community all the populations of different
organisms within a given area (all the animals in
the pond).
Ecosystem (biome) geographic area that has a
particular type of community (abiotic/biotic).
Biosphere portion of the earth in which living
things exist (lithosphere/hydrosphere/
atmosphere).

195
Fields of Biology

Traditionally, biology has been divided into two
major fields. Botany deals with plants, and
zoology with animals. Botany and zoology are
further divided into various branches and
specialized areas of study. But most branches of
biology--for example, anatomy (the study of the
structure of living things) and genetics (the
study of heredity)--apply to both plants and
animals.

196
Breaking it Down . . .

Biology may also be divided into ecology,
physiology, and systematics. Ecology deals with
the relationships among living things and between
organisms and their environment. Physiology
concerns life functions, such as digestion and
respiration. Systematics, also called taxonomy,
is the scientific classification of plants and
animals.

197
Why is Biology Important?

Biological research has greatly affected people's
lives. For example, farm production has soared as
biologists have helped develop better varieties
of plants and new agricultural techniques.
Biologists also work in industry, especially the
pharmaceutical and food industries.
Biotechnologists develop new methods for the
preparation of products using microorganisms.
Discoveries in biology have enabled doctors to
prevent, treat, or cure many diseases. Research
on the relationships between living things and
their environment has helped in the management
of wildlife and other natural
resources.

198
Prokaryote v. Eukaryote

Prokaryote a single celled organism without a
nucleus
Eukaryote - a single-celled or multi-cellular
organism whose cells contain a distinct
membrane-bound nucleus.

199
Nutrition

Autotrophs organisms that can make their own
food. Can photosynthesize. Directly or indirectly
produce food for heterotrophs.
Heterotrophs Must obtain food.
Herbivores feed on plants.
Carnivores feed on animals
Predators attack and kill prey
Scavengers feed on dead animals they find
Omnivores feed both on plants and animals
Saprobes obtain nutrients by breaking down the
remains of dead plants and animals. Bacteria and
fungus fall into this group.

200
Changes over time

Fossils physical remains of organisms.
Natural selection the process of organisms to
change over time.
Adaptation a characteristic or trait that helps
an organism survive in its environment.
Genetic variation variety in offspring.
Mutation greater variation or random changes.
Extinction When the organisms die.
Mass extinction many species die at one time.

201
Symbiotic Relationships

Relationships in which two different organisms
live in close association to the benefit of at
least one of them.
Mutualism both organisms benefit
Commensalism one organism benefits, the
other remains unaffected
Parasitism one organism
benefits, the other is harmed

202
Specializations

Biology is such a broad subject that most
biologists specialize in some area of study.
Zoology study animals
Marine Biology study life in the oceans
Herpetologist study reptiles
Ichthyologist study fish
Microbiology study viruses
and very small things.

203
Strand F Processes of Life

Skeletal framework/support
Muscular muscles/help things inside your body
move (voluntary/involuntary)
Digestive breaks down food into substances the
body can use
Excretory removes wastes
Respiratory getting O2 into body
Circulatory transports needed substances and
carries away waste

204

Nervous controls and coordinates the bodies
activities
Endocrine regulates the bodies activities by
producing hormones
Immune protects body against disease
Reproductive system involved in creating a new
organism

205

Mitosis cell division/complete process of
copying and dividing the whole cell
Plant cell v. Animal cell Plant cells can have
all the animal cells structures and a cell wall
and chloroplasts.

206
What kind of cell is this?
207
Strand F Processes of Life

Osmosis diffusion of water across a membrane
Diffusion movement from an area of higher
concentration to lesser concentration

208
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209

Endoplasmic Reticulum makes proteins and
transports materials
Mitochondria transforms the energy from the
food into a source cells can use powerhouse
Nucleus contains cells DNA
Ribosomes puts proteins together
Golgi Bodies helps package and distribute
products within the cell

210

Cytoplasm gel-like fluid that takes up most of
the space inside a cell
Cell wall stiff outer barrier of plant cell
Vacuoles holds waste products
Cell membrane structure that surrounds the
cytoplasm of a cell
Nuclear membrane structure that surrounds the
nucleus of a cell
Chloroplast contains chlorophyll

211
Strand F Processes of Life

Sexual Reproduction combining cells from two
different parents (gametes)
Asexual Reproduction one parent organism
Traits inherited from parent
Dominant allelle if present, determines trait
Recessive allelle masked if dominant allelle is
present

212
Strand F Processes of Life

Genotype set of genes carried by an organism
Phenotype physical appearance of an organism
Homozygous TT or tt
Heterozygous - Tt

213
Strand F Processes of Life

Punnett Square used to predict what traits
offspring will have

214

Adaptations structures, behaviors, or other
traits in an organism that help it to survive in
its environment.
Ie spiny leaves for cacti to reduce water loss
Beak shapes for types of seeds available
Normal differences within species is genetic
variation.
Random changes are mutations and can be harmful.
Ie a brown polar bear.

215

Fossils plant and animal
Pangeae
History of Earth

216
A bones
C heart
B ears
D lungs
217
You are Correct!
Why are A, B and D are not correct?
218
Strand G How Living Things Interact with their
Environment

Virus microscopic particle that can infect the
cells of an organism. They replicate themselves
only by infecting a host cell.

219
Organism Classification

Kingdom
Phylum
Class
Order
Family
Genus
Species

220
Classification of Living Things

Monera small, simple single prokaryotic cell
bacteria, blue-green algae, and spirochetes
Protista large, single eukaryotic cell
protozoans and algae of various types
Fungi multicellular filamentous form with
specialized eukaryotic cells
funguses, molds, mushrooms, yeasts, mildews, and
smuts
Plantae multicellular form with specialized
eukaryotic cells do not have their own means of
locomotion
mosses, ferns, woody and non-woody flowering
plants
Animalia multicellular form with specialized
eukaryotic cells have their own means of
locomotion
sponges, worms, insects, fish, amphibians,
reptiles, birds, and mammals

221

Biotic Factor living things or their materials
that directly or indirectly affect an organism in
its environment
Abiotic Factor non-living physical/chemical
factors which affect organisms in its environment
(light, temperature, type of soil/rock, ph level,
water availability, pollutants)

222
The Water Cycle

The continuous movement of water from the earths
atmosphere to the earths surface and back to the
atmosphere again.
Also known as hydrologic cycle.

223
Water Cycle Processes

Evaporation process by which liquid water
changes into water vapor (86 from ocean 14
from freshwater sources).
Transpiration process by which plants give off
water vapor into the atmosphere.
Evaportranspiration combined processes of
evaporation and transpiration.

224
Water Cycle Processes

Condensation expanding/cooling causing cloud
formation.
Precipitation process by which water falls from
clouds to the earth (i.e. rain, snow, sleet,
and/or hail). About 75 of precipitation lands on
the ocean.

225

Runoff water that flows over the land into
streams and rivers.
Groundwater water that soaks deep in soil and
rock

226
Water Budget

Continuous cycle of evapotranspiration,
condensation and precipitation.
Local water budget is usually not balanced.
lt evapotranspiration gt precipitation flooding
gt evapotranspiration lt precipitation drought

227
Water Conservation

Water uses and increased demand.
90 of water used by cities/industries is
returned as waste water.
Water Conservation
Finding other sources/Desalination (removing
salts from ocean water).

228
The Water Cycle
229
The Oxygen Cycle

Natural process that maintains the chemical
balance of oxygen in the atmosphere.
Animals, bacteria, plants, forest fires, burning
of fuels (industry) consume oxygen.
Land and ocean plants produce large quantities of
oxygen during daylight.
The oxygen content is in a state of balance.

Science FCAT Benchmark Review - PowerPoint PPT Presentation

Science FCAT Benchmark Review

Science FCAT Benchmark Review – PowerPoint PPT presentation