Content Expectations
Science, K-8 (2007)
Discipline 1 Science Processes
Standard: Inquiry Process
K-7 Standard S.IP: Develop an understanding that scientific inquiry and
reasoning involves observing, questioning, investigating, recording, and
developing solutions to problems
S.IP.E.1 -
Inquiry involves generating questions, conducting
investigations, and developing solutions to problems through
reasoning and observation.
S.IP.00.11 -
Make purposeful observation of the natural world using the
appropriate senses.
S.IP.00.12 -
Generate questions based on observations.
S.IP.00.13 -
Plan and conduct simple investigations.
S.IP.00.14 -
Manipulate simple tools (for example: hand lens, pencils,
balances, non-standard objects for measurement) that aid
observation and data collection.
S.IP.00.15 -
Make accurate measurements with appropriate (non-standard)
units for the measurement tool.
S.IP.00.16 -
Construct simple charts from data and observations.
S.IP.01.11 -
Make purposeful observation of the natural world using the
appropriate senses.
S.IP.01.12 -
Generate questions based on observations.
S.IP.01.13 -
Plan and conduct simple investigations.
S.IP.01.14 -
Manipulate simple tools (for example: hand lens, pencils, rulers,
thermometers, rain gauges, balances, non-standard objects for
measurement) that aid observation and data collection.
S.IP.01.15 -
Make accurate measurements with appropriate (non-standard)
units for the measurement tool.
S.IP.01.16 -
Construct simple charts from data and observations.
S.IP.02.11 -
Make purposeful observation of the natural world using the
appropriate senses.
S.IP.02.12 -
Generate questions based on observations.
S.IP.02.13 -
Plan and conduct simple investigations.
S.IP.02.14 -
Manipulate simple tools (ruler, meter stick, measuring cups, hand
lens, thermometer, balance) that aid observation and
data collection.
S.IP.02.15 -
Make accurate measurements with appropriate units (meter,
centimeter) for the measurement tool.
S.IP.02.16 -
Construct simple charts and graphs from data and observations.
S.IP.03.11 -
Make purposeful observation of the natural world using the
appropriate senses.
S.IP.03.12 -
Generate questions based on observations.
S.IP.03.13 -
Plan and conduct simple and fair investigations.
S.IP.03.14 -
Manipulate simple tools that aid observation and data collection
(for example: hand lens, balance, ruler, meter stick, measuring
cup, thermometer, spring scale, stop watch/timer).
S.IP.03.15 -
Make accurate measurements with appropriate units
(centimeters, meters, Celsius, grams, seconds, minutes) for the
measurement tool.
S.IP.03.16 -
Construct simple charts and graphs from data and observations.
S.IP.04.11 -
Make purposeful observation of the natural world using the
appropriate senses.
S.IP.04.12 -
Generate questions based on observations.
S.IP.04.13 -
Plan and conduct simple and fair investigations.
S.IP.04.14 -
Manipulate simple tools that aid observation and data collection
(for example: hand lens, balance, ruler, meter stick, measuring
cup, thermometer, spring scale, stop watch/timer, graduated
cylinder/beaker).
S.IP.04.15 -
Make accurate measurements with appropriate units (millimeters
centimeters, meters, milliliters, liters, Celsius, grams, seconds,
minutes) for the measurement tool.
S.IP.04.16 -
Construct simple charts and graphs from data and observations.
S.IP.M.1 -
Inquiry involves generating questions, conducting
investigations, and developing solutions to problems through
reasoning and observation.
S.IP.05.11 -
Generate scientific questions based on observations,
investigations, and research.
S.IP.05.12 -
Design and conduct scientific investigations.
S.IP.05.13 -
Use tools and equipment (spring scales, stop watches, meter
sticks and tapes, models, hand lens) appropriate to scientific
investigations.
S.IP.05.14 -
Use metric measurement devices in an investigation.
S.IP.05.15 -
Construct charts and graphs from data and observations.
S.IP.05.16 -
Identify patterns in data.
S.IP.06.11 -
Generate scientific questions based on observations,
investigations, and research.
S.IP.06.12 -
Design and conduct scientific investigations.
S.IP.06.13 -
Use tools and equipment (spring scales, stop watches, meter
sticks and tapes, models, hand lens, thermometer, models,
sieves, microscopes) appropriate to scientific investigations.
S.IP.06.14 -
Use metric measurement devices in an investigation.
S.IP.06.15 -
Construct charts and graphs from data and observations.
S.IP.06.16 -
Identify patterns in data.
S.IP.07.11 -
Generate scientific questions based on observations,
investigations, and research.
S.IP.07.12 -
Design and conduct scientific investigations.
S.IP.07.13 -
Use tools and equipment (spring scales, stop watches, meter
sticks and tapes, models, hand lens, thermometer, models,
sieves, microscopes, hot plates, pH meters) appropriate to
scientific investigations.
S.IP.07.14 -
Use metric measurement devices in an investigation.
S.IP.07.15 -
Construct charts and graphs from data and observations.
S.IP.07.16 -
Identify patterns in data.
Standard: Inquiry Analysis and Communication
K-7 Standard S.IA: Develop an understanding that scientific inquiry and
investigations require analysis and communication of findings, using
appropriate technology.
S.IA.E.1 -
Inquiry includes an analysis and presentation of findings
that lead to future questions, research, and investigations.
S.IA.00.12 -
Share ideas about science through purposeful conversation.
S.IA.00.13 -
Communicate and present findings of observations.
S.IA.00.14 -
Develop strategies for information gathering (ask an expert, use
a book, make observations, conduct simple investigations, and
watch a video).
S.IA.01.12 -
Share ideas about science through purposeful conversation.
S.IA.01.13 -
Communicate and present findings of observations.
S.IA.01.14 -
Develop strategies for information gathering (ask an expert, use
a book, make observations, conduct simple investigations, and
watch a video).
S.IA.02.12 -
Share ideas about science through purposeful conversation.
S.IA.02.13 -
Communicate and present findings of observations.
S.IA.02.14 -
Develop strategies and skills for information gathering and
problem solving (books, internet, ask an expert, observation,
investigation, technology tools).
S.IA.03.11 -
Summarize information from charts and graphs to answer
scientific questions.
S.IA.03.12 -
Share ideas about science through purposeful conversation in
collaborative groups.
S.IA.03.13 -
Communicate and present findings of observations and
investigations.
S.IA.03.14 -
Develop research strategies and skills for information gathering
and problem solving.
S.IA.03.15 -
Compare and contrast sets of data from multiple trials of a
science investigation to explain reasons for differences.
S.IA.04.11 -
Summarize information from charts and graphs to answer
scientific questions.
S.IA.04.12 -
Share ideas about science through purposeful conversation in
collaborative groups.
S.IA.04.13 -
Communicate and present findings of observations and
investigations.
S.IA.04.14 -
Develop research strategies and skills for information gathering
and problem solving.
S.IA.04.15 -
Compare and contrast sets of data from multiple trials of a
science investigation to explain reasons for differences.
S.IA.M.1 -
Inquiry includes an analysis and presentation of findings
that lead to future questions, research, and investigations.
S.IA.05.11 -
Analyze information from data tables and graphs to answer
scientific questions.
S.IA.05.12 -
Evaluate data, claims, and personal knowledge through
collaborative science discourse.
S.IA.05.13 -
Communicate and defend findings of observations and
investigations using evidence.
S.IA.05.14 -
Draw conclusions from sets of data from multiple trials of a
scientific investigation.
S.IA.05.15 -
Use multiple sources of information to evaluate strengths and
weaknesses of claims, arguments, or data.
S.IA.06.11 -
Analyze information from data tables and graphs to answer
scientific questions.
S.IA.06.12 -
Evaluate data, claims, and personal knowledge through
collaborative science discourse.
S.IA.06.13 -
Communicate and defend findings of observations and
investigations using evidence.
S.IA.06.14 -
Draw conclusions from sets of data from multiple trials of a
scientific investigation.
S.IA.06.15 -
Use multiple sources of information to evaluate strengths and
weaknesses of claims, arguments, or data.
S.IA.07.11 -
Analyze information from data tables and graphs to answer
scientific questions.
S.IA.07.12 -
Evaluate data, claims, and personal knowledge through
collaborative science discourse.
S.IA.17.13 -
Communicate and defend findings of observations and
investigations.
S.IA.07.14 -
Draw conclusions from sets of data from multiple trials of a
scientific investigation to draw conclusions.
S.IA.07.15 -
Use multiple sources of information to evaluate strengths and
weaknesses of claims, arguments, or data.
Standard: Reflection and Social Implications
K-7 Standard S.RS: Develop an understanding that claims and evidence
for their scientific merit should be analyzed. Understand how scientists
decide what constitutes scientific knowledge. Develop an understanding of
the importance of reflection on scientific knowledge and its application to new
situations to better understand the role of science in society and technology.
S.RS.E.1 -
Reflecting on knowledge is the application
of scientific knowledge to new and different situations.
Reflecting on knowledge requires careful
analysis of evidence that guides decision-making
and the application of science throughout history and
within society.
S.RS.00.11 -
Demonstrate scientific concepts through various illustrations,
performances, models, exhibits, and activities.
S.RS.01.11 -
Demonstrate scientific concepts through various illustrations,
performances, models, exhibits, and activities.
S.RS.01.12 -
Recognize that science investigations are done more than one
time.
S.RS.02.11 -
Demonstrate scientific concepts through various illustrations,
performances, models, exhibits, and activities.
S.RS.02.13 -
Recognize that when a science investigation is done the way it
was done before, similar results are expected.
S.RS.02.15 -
Use evidence when communicating scientific ideas.
S.RS.02.16 -
Identify technology used in everyday life.
S.RS.03.11 -
Demonstrate scientific concepts through various
illustrations, performances, models, exhibits, and
activities.
S.RS.03.14 -
Use data/samples as evidence to separate fact from
opinion.
S.RS.03.15 -
Use evidence when communicating scientific ideas.
S.RS.03.16 -
Identify technology used in everyday life.
S.RS.03.17 -
Identify current problems that may be solved through
the use of technology.
S.RS.03.18 -
Describe the effect humans and other organisms have
on the balance of the natural world.
S.RS.03.19 -
Describe how people have contributed to science
throughout history and across cultures.
S.RS.04.11 -
Demonstrate scientific concepts through various
illustrations, performances, models, exhibits, and
activities.
S.RS.04.14 -
Use data/samples as evidence to separate fact from
opinion.
S.RS.04.15 -
Use evidence when communicating scientific ideas.
S.RS.04.16 -
Identify technology used in everyday life.
S.RS.04.17 -
Identify current problems that may be solved through
the use of technology.
S.RS.04.18 -
Describe the effect humans and other organisms have
on the balance of the natural world.
S.RS.04.19 -
Describe how people have contributed to science
throughout history and across cultures.
S.RS.M.1 -
Reflecting on knowledge is the application of scientific
knowledge to new and different situations. Reflecting on knowledge
requires careful analysis of evidence that guides decision-making
and the application of science throughout history and within society.
S.RS.05.11 -
Evaluate the strengths and weaknesses of claims,
arguments, and data.
S.RS.05.12 -
Describe limitations in personal and scientific
knowledge.
S.RS.05.13 -
Identify the need for evidence in making scientific
decisions.
S.RS.05.15 -
Demonstrate scientific concepts through various
illustrations, performances, models, exhibits, and
activities.
S.RS.05.16 -
Design solutions to problems using technology.
S.RS.05.17 -
Describe the effect humans and other organisms have
on the balance in the natural world.
S.RS.05.19 -
Describe how science and technology have advanced
because of the contributions of many people
throughout history and across cultures.
S.RS.06.11 -
Evaluate the strengths and weaknesses of claims,
arguments, and data.
S.RS.06.12 -
Describe limitations in personal and scientific
knowledge.
S.RS.06.13 -
Identify the need for evidence in making scientific
decisions.
S.RS.06.14 -
Evaluate scientific explanations based on current
evidence and scientific principles.
S.RS.06.15 -
Demonstrate scientific concepts through various
illustrations, performances, models, exhibits, and
activities.
S.RS.06.16 -
Design solutions to problems using technology.
S.RS.06.17 -
Describe the effect humans and other organisms have
on the balance of the natural world.
S.RS.06.18 -
Describe what science and technology can and cannot
reasonably contribute to society.
S.RS.06.19 -
Describe how science and technology have advanced
because of the contributions of many people
throughout history and across cultures.
S.RS.07.11 -
Evaluate the strengths and weaknesses of claims,
arguments, and data.
S.RS.07.12 -
Describe limitations in personal and scientific
knowledge.
S.RS.07.13 -
Identify the need for evidence in making scientific
decisions.
S.RS.07.14 -
Evaluate scientific explanations based on current
evidence and scientific principles.
S.RS.07.15 -
Demonstrate scientific concepts through various
illustrations, performances, models, exhibits, and
activities.
S.RS.07.16 -
Design solutions to problems using technology.
S.RS.07.17 -
Describe the effect humans and other organisms have
on the balance of the natural world.
S.RS.07.18 -
Describe what science and technology can and cannot
reasonably contribute to society.
S.RS.07.19 -
Describe how science and technology have advanced
because of the contributions of many people
throughout history and across cultures.
Discipline 2 Physical Science
Standard: Force and Motion
K-7 Standard P.FM: Develop an understanding that the position
and/or motion of an object is relative to a point of reference.
Understand forces affect the motion and speed of an object and
that the net force on an object is the total of all of the forces
acting on it. Understand the Earth pulls down on objects with a
force called gravity. Develop an understanding that some forces
are in direct contact with objects, while other forces are not
in direct contact with objects.
P.FM.E.1 -
Position- A position of an object can be described
by locating the object relative to other objects or a
background. The description of the motion of an object
from one observer’s view may be different from that
reported from a different observer’s view.
P.FM.00.11 -
Compare the position of an object (for example:
above, below, in front of, behind, on) in relation
to other objects around it.
P.FM.00.12 -
Describe the motion of an object (for example:
away from or closer to) from different observers’
views.
P.FM.E.2 -
Gravity- Earth pulls down on all objects with a
force called gravity. With very few exceptions, objects fall
to the ground no matter where the object is on the Earth.
P.FM.00.21 -
Observe how objects fall toward the earth.
P.FM.03.22 -
Identify the force that pulls objects towards the
Earth.
P.FM.E.3 -
Force- A force is either a push or a pull. The
motion of objects can be changed by forces. The size of
the change is related to the size of the force. The change
is also related to the weight (mass) of the object on
which the force is being exerted. When an object does
not move in response to a force, it is because another force
is being applied by the environment.
P.FM.00.31 -
Demonstrate pushes and pulls.
P.FM.00.32 -
Observe that objects initially at rest will move in the
direction of the push or pull.
P.FM.00.33 -
Observe how pushes and pulls can change the speed
or direction of moving objects.
P.FM.00.34 -
Observe how shape (for example: cone, cylinder,
sphere), size, and weight of an object can affect
motion.
P.FM.03.35 -
Describe how a push or a pull is a force.
P.FM.03.36 -
Relate a change in motion of an object to the force
that caused the change of motion.
P.FM.03.37 -
Demonstrate how the change in motion of an object
is related to the strength of the force acting upon the
object and to the mass of the object.
P.FM.03.38 -
Demonstrate when an object does not move in
response to a force, it is because another force is
acting on it.
P.FM.E.4 -
Speed- An object is in motion when its position is
changing. The speed of an object is defined by how far it
travels divided by the amount of time it took to travel that
far.
P.FM.03.41 -
Compare and contrast the motion of objects in terms
of direction.
P.FM.03.42 -
Identify changes in motion (change direction,
speeding up, slowing down).
P.FM.03.43 -
Calculate the speed of an object based on the
distance it travels divided by the amount of time it
took to travel that distance.
P.FM.M.2 -
Force Interactions- Some forces between
objects act when the objects are in direct contact
(touching), such as friction and air resistance, or when they
are not in direct contact (not touching), such as magnetic
force, electrical force, and gravitational force.
P.FM.05.21 -
Distinguish between contact forces and non-contact
forces.
P.FM.05.22 -
Demonstrate contact and non-contact forces to
change the motion of an object.
P.FM.M.3 -
Force- Forces have a magnitude and direction.
Forces can be added. The net force on an object is the sum
of all of the forces acting on the object. The speed and/or
direction of motion of an object changes when a non-zero
net force is applied to it. A balanced force on an object
does not change the motion of the object (the object
either remains at rest or continues to move at a constant
speed in a straight line).
P.FM.05.31 -
Describe what happens when two forces act on an
object in the same or opposing directions.
P.FM.05.32 -
Describe how constant motion is the result of
balanced (zero net) forces.
P.FM.05.33 -
Describe how changes in the motion of objects are
caused by a non-zero net (unbalanced) force.
P.FM.05.34 -
Relate the size of change in motion to the strength of
unbalanced forces and the mass of the object.
P.FM.M.4 -
Speed- Motion can be described by a change
in position relative to a point of reference. The motion of an
object can be described by its speed and the direction it is
moving. The position and speed of an object can be
measured and graphed as a function of time.
P.FM.05.41 -
Explain the motion of an object relative to its point of
reference.
P.FM.05.42 -
Describe the motion of an object in terms of distance,
time and direction, as the object moves, and in
relationship to other objects.
P.FM.05.43 -
Illustrate how motion can be measured and
represented on a graph.
Standard: Properties of Matter
K-7 Standard P.PM: Develop an understanding that all matter
has observable attributes with physical and chemical properties
that are described, measured, and compared Understand that
states of matter exist as solid, liquid, or gas; and have physical
and chemical properties. Understand all matter is composed of
combinations of elements, which are organized by common
attributes and characteristics on the Periodic Table. Understand
that substances can be classified as mixtures or compounds
and according to their physical and chemical properties.
P.PM.E.1 -
Physical Properties- All objects and substances have
physical properties that can be measured.
P.PM.01.11 -
Demonstrate the ability to sort objects according to
observable attributes such as color, shape, size, sinking or
floating.
P.PM.02.12 -
Describe objects and substances according to their
properties (color, size, shape, texture, hardness, liquid
or solid, sinking or floating).
P.PM.02.13 -
Measure the length of objects using rulers
(centimeters) and meter sticks (meters).
P.PM.02.14 -
Measure the volume of liquids using common
measuring tools (measuring cups, measuring spoons).
P.PM.02.15 -
Compare the weight of objects using balances.
P.PM.04.16 -
Measure the weight (spring scale) and mass
(balances in grams or kilograms) of objects.
P.PM.04.17 -
Measure volumes of liquids and capacities of
containers in milliliters and liters.
P.PM.04.18 -
Demonstrate the use of centimeter cubes poured into
a container to estimate the container’s capacity.
P.PM.E.2 -
States of Matter- Matter exists in several different
states: solids, liquids and gases. Each state of matter has
unique physical properties. Gases are easily compressed but
liquids and solids do not compress easily. Solids have their own
particular shapes, but liquids and gases take the shape of the
container.
P.PM.01.21 -
Demonstrate that water as a solid keeps its own shape
(ice).
P.PM.01.22 -
Demonstrate that water as a liquid takes on the shape of
various containers.
P.PM.04.23 -
Compare and contrast the states (solids, liquids,
gases) of matter.
P.PM.E.3 -
Magnets- Magnets can repel or attract other magnets.
Magnets can also attract certain non-magnetic objects at a
distance.
P.PM.01.31 -
Identify materials that are attracted by magnets.
P.PM.01.32 -
Observe that like poles of a magnet repel and unlike poles
of a magnet attract.
P.PM.04.33 -
Demonstrate magnetic field by observing the
patterns formed with iron filings using a variety of
magnets.
P.PM.04.34 -
Demonstrate that non-magnetic objects are affected
by the strength of the magnet and the distance away
from the magnet.
P.PM.E.4 -
Material Composition- Some objects are
composed of a single substance, while other
objects are composed of more than one substance.
P.PM.02.41 -
Classify objects as single substances (ice, silver,
sugar, salt) or mixtures (salt and pepper, mixed dry
beans).
P.PM.E.5 -
Conductive and Reflective Properties- Objects
vary to the extent they absorb and reflect light energy and
conduct heat and electricity.
P.PM.03.51 -
Demonstrate how some materials are heated more
than others by light that shines on them.
P.PM.03.52 -
Explain how we need light to see objects: light from a
source reflects off objects and enters our eyes.
P.PM.04.53 -
Identify objects that are good conductors or poor
conductors of heat and electricity.
P.PM.M.1 -
Chemical Properties- Matter has chemical
properties. The understanding of chemical properties helps
to explain how new substances are formed.
P.PM.07.11 -
Classify substances by their chemical properties
(flammability, pH, acid-base indicators, reactivity).
P.PM.M.2 -
Elements and Compounds- Elements are composed
of a single kind of atom that are grouped into families with
similar properties on the periodic table. Compounds are
composed of two or more different elements. Each element
and compound has a unique set of physical and chemical
properties such as boiling point, density, color, conductivity,
and reactivity.
P.PM.07.21 -
Identify the smallest component that makes up an
element.
P.PM.07.22 -
Describe how the elements within the Periodic Table
are organized by similar properties into families
(highly reactive metals, less reactive metals, highly
reactive nonmetals, and some almost completely
non-reactive gases).
P.PM.07.23 -
Illustrate the structure of molecules using models or
drawings (water, carbon dioxide, salt).
P.PM.07.24 -
List examples of physical and chemical properties of
elements and compounds (boiling point, density, color,
conductivity, reactivity).
Standard: Energy
K-7 Standard P.EN: Develop an understanding that there are
many forms of energy (such as heat, light, sound, and electrical)
and that energy is transferable by convection, conduction, or
radiation. Understand energy can be in motion, called kinetic; or it
can be stored, called potential. Develop an understanding that as
temperature increases, more energy is added to a system.
Understand nuclear reactions in the sun produce light and heat for
the Earth.
P.EN.E.1 -
Forms of Energy- Heat, electricity, light, and
sound are forms of energy.
P.EN.03.11 -
Identify light and sound as forms of energy.
P.EN.04.12 -
Identify heat and electricity as forms of energy.
P.EN.E.2 -
Light Properties- Light travels in straight lines.
Shadows result from light not being able to pass through an
object. When light travels at an angle from one substance to
another (air and water), it changes direction.
P.EN.03.21 -
Demonstrate that light travels in a straight line and
that shadows are made by placing an object in a path
of light.
P.EN.03.22 -
Demonstrate what happens to light when it travels
from water to air. (straw half in water looks bent).
P.EN.E.3 -
Sound- Vibrating objects produce sound. The
pitch of sound varies by changing the rate of vibration.
P.EN.03.31 -
Relate sounds to their sources of vibrations (for
example: a musical note produced by a vibrating
guitar string, the sounds of a drum made by the
vibrating drum head).
P.EN.03.32 -
Distinguish the effect of fast or slow vibrations as
pitch.
P.EN.E.4 -
Energy and Temperature- Increasing the
temperature of any substance requires the addition of
energy.
P.EN.04.41 -
Demonstrate how temperature can be increased in a
substance by adding energy.
P.EN.04.42 -
Describe heat as the energy produced when
substances burn, certain kinds of materials rub
against each other, and when electricity flows through
wire.
P.EN.04.43 -
Describe how heat is produced through electricity,
rubbing, and burning.
P.EN.E.5 -
Electrical Circuits- Electrical circuits transfer
electrical energy and produce magnetic fields.
P.EN.04.51 -
Explain how electrical energy is transferred and
changed through the use of a simple circuit.
P.EN.04.52 -
Create a simple working electromagnet and explain
the conditions necessary to make the electromagnet.
P.EN.M.1 -
Kinetic and Potential Energy- Objects and
substances in motion have kinetic energy. Objects and
substances may have potential energy due to their relative
positions in a system. Gravitational, elastic, and chemical
energy are all forms of potential energy.
P.EN.06.11 -
Identify kinetic or potential energy in everyday
situations (for example: stretched rubber band,
objects in motion, ball on a hill, food energy).
P.EN.06.12 -
Demonstrate the transformation between potential
and kinetic energy in simple mechanical systems (for
example: roller coasters, pendulums).
P.EN.M.4 -
Energy Transfer- Energy is transferred from a
source to a receiver by radiation, conduction,
and convection. When energy is transferred from a
source to a receiver, the quantity of energy before the
transfer is equal to the quantity of energy after the
transfer.
P.EN.06.41 -
Explain how different forms of energy can be
transferred from one place to another by radiation,
conduction, or convection.
P.EN.06.42 -
Illustrate how energy can be transferred while no
energy is lost or gained in the transfer.
P.EN.07.43 -
Explain how light energy is transferred to chemical
energy through the process of photosynthesis.
P.EN.M.3 -
Waves and Energy-Waves have energy and
transfer energy when they interact with matter. Examples
of waves include sound waves, seismic waves, waves on
water, and light waves.
P.EN.07.31 -
Identify examples of waves, including sound waves,
seismic waves, and waves on water.
P.EN.07.32 -
Describe how waves are produced by vibrations in
matter.
P.EN.07.33 -
Demonstrate how waves transfer energy when they
interact with matter (for example: tuning fork in
water, waves hitting a beach, earthquake knocking
over buildings).
P.EN.M.6 -
Solar Energy Effects- Nuclear reactions take place
in the sun producing heat and light. Only a tiny fraction of
the light energy from the sun reaches Earth, providing
energy to heat the Earth.
P.EN.07.61 -
Identify that nuclear reactions take place in the sun,
producing heat and light.
P.EN.07.62 -
Explain how only a tiny fraction of light energy from
the sun is transformed to heat energy on Earth.
Standard: Changes in Matter
K-7 Standard P.CM: Develop an understanding of changes in
the state of matter in terms of heating and cooling, and in terms of
arrangement and relative motion of atoms and molecules.
Understand the differences between physical and chemical
changes. Develop an understanding of the conservation of mass.
Develop an understanding of products and reactants in a chemical
change.
P.CM.E.1 -
Changes in State- Matter can be changed from
one state (liquid, solid, gas) to another and then back
again. This may be caused by heating and cooling.
P.CM.04.11 -
Explain how matter can change from one state
(liquid, solid, gas) to another by heating and cooling.
P.CM.M.1 -
Changes in State- Matter changing from state to
state can be explained by using models which show that
matter is composed of tiny particles in motion. When
changes of state occur, the atoms and/or molecules are not
changed in structure. When the changes in state occur,
mass is conserved because matter is not created or
destroyed.
P.CM.06.11 -
Describe and illustrate changes in state, in terms of
the arrangement and relative motion of the atoms or
molecules.
P.CM.06.12 -
Explain how mass is conserved as it changes from
state to state in a closed system.
P.CM.M.2 -
Chemical Changes- Chemical changes occur
when two elements and/or compounds react and
produce new substances. These new substances have
different physical and chemical properties than the
original elements and/or compounds. During the chemical
change, the number and kind of atoms in the reactants are
the same as the number and kind of atoms in the products.
Mass is conserved during chemical changes. The mass of
the reactants is the same as the mass of the products.
P.CM.07.21 -
Identify evidence of chemical change through color,
gas formation, solid formation, and temperature
change.
P.CM.07.22 -
Compare and contrast the chemical properties of a
new substance with the original after a chemical
change.
P.CM.07.23 -
Describe the physical properties and chemical
properties of the products and reactants in a chemical
change.
Discipline 3 Life Science
Standard: Organization of Living Things
K-7 Standard L.OL: Develop an understanding that plants and
animals (including humans) have basic requirements for
maintaining life which include the need for air, water and a source
of energy. Understand that all life forms can be classified as
producers, consumers, or decomposers as they are all part of a
global food chain where food/energy is supplied by plants which
need light to produce food/ energy. Develop an understanding
that plants and animals can be classified by observable traits and
physical characteristics. Understand that all living organisms are
composed of cells and they exhibit cell growth and division.
Understand that all plants and animals have a definite life cycle,
body parts, and systems to perform specific life functions.
L.OL.E.1 -
Life Requirements- Organisms have basic needs.
Animals and plants need air, water, and food. Plants also
require light. Plants and animals use food as a source of
energy and as a source of building material for growth and
repair.
L.OL.00.11 -
Identify that living things have basic needs.
L.OL.00.12 -
Identify and compare living and nonliving things.
L.OL.01.13 -
Identify the needs of animals.
L.OL.02.14 -
Identify the needs of plants.
L.OL.04.15 -
Determine that plants require air, water, light, and a
source of energy and building material for growth and
repair.
L.OL.04.16 -
Determine that animals require air, water, and a
source of energy and building material for growth
and repair.
L.OL.E.2 -
Life Cycles- Plants and animals have life cycles. Both
plants and animals begin life and develop into adults, reproduce,
and eventually die. The details of this life cycle are different for
different organisms.
L.OL.01.21 -
Describe the life cycle of animals including the following
stages: egg, young, adult; egg, larva, pupa, adult.
L.OL.02.22 -
Describe the life cycle of familiar flowering plants
including the following stages: seed, plant, flower,
and fruit.
L.OL.E.3 -
Structures and Functions- Organisms have
different structures that serve different functions in
growth, survival, and reproduction.
L.OL.03.31 -
Describe the function of the following plant parts:
flower, stem, root and leaf.
L.OL.03.32 -
Identify and compare structures in animals used for
controlling body temperature, support, movement,
food-getting, and protection (for example: fur, wings,
teeth, claws).
L.OL.E.4 -
Classification- Organisms can be classified on the basis
of observable characteristics.
L.OL.03.41 -
Classify plants on the basis of observable physical
characteristics (roots, leaves, stems, and flowers).
L.OL.03.42 -
Classify animals on the basis of observable physical
characteristics (backbone, skin, shell, limbs, scales).
L.OL.M.4 -
Animal Systems- Multicellular organisms may
have specialized systems that perform functions which
serve the needs of the organism.
L.OL.05.41 -
Identify the general purpose of selected animal
systems (digestive, circulatory, respiratory, skeletal,
muscular, nervous, excretory, and reproductive).
L.OL.05.42 -
Explain how animal systems (digestive, circulatory,
respiratory, skeletal, muscular, nervous, excretory,
and reproductive) work together to perform selected
activities.
L.OL.M.5 -
Producers, Consumers, and Decomposers- All
animals, including humans, are consumers that meet
their energy by eating other organisms or their
products. Consumers break down the structures of
the organisms they eat to make the materials they need to
grow and function. Decomposers, including bacteria and
fungi, use dead organisms or their products to meet their
energy needs.
L.OL.06.51 -
Classify organisms (producers, consumers, and
decomposers) based on their source of energy for
growth and development.
L.OL.06.52 -
Distinguish between the ways in which consumers and
decomposers obtain energy.
L.OL.M.2 -
Cell Functions- All organisms are composed
of cells, from one cell to many cells. In multicellular
organisms, specialized cells perform specialized functions.
Organs and organ systems are composed of cells,
and function to serve the needs of cells for food, air,
and waste removal. The way in which cells function
is similar in all living organisms.
L.OL.07.21 -
Recognize that all organisms are composed of cells
(single cell organisms, multicellular organisms).
L.OL.07.22 -
Explain how cells make up different body tissues,
organs, and organ systems.
L.OL.07.23 -
Describe how cells in all multicellular organisms are
specialized to take in nutrients, which they use to
provide energy for the work that cells do and to make
the materials that a cell or organism needs.
L.OL.07.24 -
Recognize that cells function in a similar way in all
organisms.
L.OL.M.3 -
Growth and Development- Following fertilization,
cell division produces a small cluster of cells that then
differentiate by appearance and function to form the basic
tissue of an embryo.
L.OL.07.31 -
Describe growth and development in terms of increase
of cell number and/or cell size.
L.OL.07.32 -
Examine how through cell division, cells can become
specialized for specific functions.
L.OL.M.6 -
Photosynthesis- Plants are producers; they use
the energy from light to make sugar molecules from the
atoms of carbon dioxide and water. Plants use these
sugars along with minerals from the soil to form fats,
proteins, and carbohydrates. These products can be used
immediately, incorporated into the cells of a plant as the
plant grows, or stored for later use.
L.OL.07.61 -
Recognize the need for light to provide energy for the
production of carbohydrates, proteins and fats.
L.OL.07.62 -
Explain that carbon dioxide and water are used to
produce carbohydrates, proteins, and fats.
L.OL.07.63 -
Describe evidence that plants make, use and store
food.
Standard: Heredity
K-7 Standard L.HE: Develop an understanding that all life forms must
reproduce to survive. Understand that characteristics of mature plants
and animals may be inherited or acquired and that only inherited traits
are passed on to their young. Understand that inherited traits can be
influenced by changes in the environment and by genetics.
L.HE.E.1 -
Observable Characteristics- Plants and animals share
many, but not all, characteristics of their parents.
L.HE.01.11 -
Identify characteristics (for example: body coverings,
beak shape, number of legs, body parts) that are passed on
from parents to young.
L.HE.01.12 -
Classify young animals based on characteristics that are
passed on from parents (for example: dogs/puppies,
cats/kittens, cows/calves, chicken/chicks).
L.HE.02.13 -
Identify characteristics of plants (for example: leaf
shape, flower type, color, size) that are passed
on from parents to young.
L.HE.M.1 -
Inherited and Acquired Traits - The
characteristics of organisms are influenced by heredity and
environment. For some characteristics, inheritance is more
important; for other characteristics, interactions with the
environment are more important.
L.HE.05.11 -
Explain that the traits of an individual are influenced
by both the environment and the genetics of the
individual.
L.HE.05.12 -
Distinguish between inherited and acquired traits.
L.HE.M.2 -
Reproduction- Reproduction is a characteristic of
all living systems; because no individual organism
lives forever, reproduction is essential to the continuation
of every species. Some organisms reproduce asexually.
Other organisms reproduce sexually.
L.HE.07.21 -
Compare how characteristics of living things are
passed on through generations, both asexually and
sexually.
L.HE.07.22 -
Compare and contrast the advantages and
disadvantages of sexual vs. asexual reproduction.
Standard: Evolution
K-7 Standard L.EV: Develop an understanding that plants and animals
have observable parts and characteristics that help them survive and
flourish in their environments. Understand that fossils provide evidence that
life forms have changed over time and were influenced by changes in
environmental conditions. Understand that life forms either change
(evolve) over time or risk extinction due to environmental changes
and describe how scientists identify the relatedness of various organisms
based on similarities in anatomical features.
L.EV.E.1 -
Environmental Adaptation- Different kinds of
organisms have characteristics that help them to live in
different environments.
L.EV.03.11 -
Relate characteristics and functions of observable parts in
a variety of plants that allow them to live in their
environment (for example: leaf shape, thorns,
odor, color).
L.EV.03.12 -
Relate characteristics and functions of observable
body parts to the ability of animals to live in their
environment(for example: sharp teeth, claws, color, body
covers).
L.EV.E.2 -
Survival- Individuals of the same kind differ in
their characteristics, and sometimes the differences give
individuals an advantage in surviving and reproducing.
L.EV.04.21 -
Identify individual differences (for example: color, leg
length, size, wing size) in organisms of the same kind.
L.EV.04.22 -
Identify how variations in physical characteristics of
individual organisms give them an advantage for
survival and reproduction.
L.EV.M.1 -
Species Adaptation and Survival- Species with
certain traits are more likely than others to survive
and have offspring in particular environments. When an
environment changes, the advantage or disadvantage
of the species’ characteristics can change. Extinction of
a species occurs when the environment changes and
the characteristics of a species are insufficient to allow
survival.
L.EV.05.11 -
Explain how behavioral characteristics (adaptation,
instinct, learning, habit) of animals help them to
survive in their environment.
L.EV.05.12 -
Describe the physical characteristics (traits) of
organisms that help them survive in their
environment.
L.EV.05.13 -
Describe how fossils provide evidence about how
living things and environmental conditions have
changed.
L.EV.05.14 -
Analyze the relationship of environmental change and
catastrophic events (for example: volcanic eruption,
floods, asteroid impacts, tsunami) to species extinction.
L.EV.M.2 -
Relationships Among Organisms- Similarities
among organisms are found in anatomical features, which
can be used to infer the degree of relatedness among
organisms. In classifying organisms, biologists consider
details of internal and external structures to be more
important than behavior or general appearance.
L.EV.05.21 -
Relate degree of similarity in anatomical features to
the classification of contemporary organisms.
Standard: Ecosystems
K-7 Standard L.EC: Develop an understanding of the interdependence
of the variety of populations, communities and ecosystems, including those in the
Great Lakes region. Develop an understanding of different types of
interdependence and that biotic (living) and abiotic (non-living) factors affect the
balance of an ecosystem. Understand that all organisms cause changes,
some detrimental and others beneficial, in the environment where they live.
L.EC.E.1 -
Interactions- Organisms interact in various ways
including providing food and shelter to one another. Some
interactions are helpful: others are harmful to the organism
and other organisms.
L.EC.04.11 -
Identify organisms as part of a food chain or food web.
L.EC.E.2 -
Changed Environment Effects- When the environment
changes, some plants and animals survive to reproduce; others die or
move to new locations.
L.EC.04.21 -
Explain how environmental changes can produce a
change in the food web.
L.EC.M.1 -
Interactions of Organisms- Organisms of
one species form a population. Populations of
different organisms interact and form communities. Living
communities and nonliving factors that interact with them
form ecosystems.
L.EC.06.11 -
List examples of populations, communities, and
ecosystems including the Great Lakes region.
L.EC.M.2 -
Relationships of Organisms- Two types of
organisms may interact with one another in several ways:
They may be in a producer/consumer, predator/
prey, or parasite/host relationship. Some organisms
may scavenge or decompose another. Relationships may be
competitive or mutually beneficial. Some species have
become so adapted to each other that neither could survive
without the other.
L.EC.06.21 -
Describe common patterns of relationships between
and among populations (competition, parasitism,
symbiosis, predator/prey).
L.EC.06.22 -
Explain how two populations of organisms can be
mutually beneficial and how that can lead to
interdependency.
L.EC.06.23 -
Predict how changes in one population might affect
other populations based upon their relationships in the
food web.
L.EC.M.3 -
Biotic and Abiotic Factors- The number
of organisms and populations an ecosystem can support
depends on the biotic (living) resources available and
abiotic (nonliving) factors, such as quality of light
and water, range of temperatures and soil composition.
L.EC.06.31 -
Identify the living (biotic) and nonliving (abiotic)
components of an ecosystem.
L.EC.06.32 -
Identify the factors in an ecosystem that influence
changes in population size.
L.EC.M.4 -
Environmental Impact of Organisms- All
organisms (including humans) cause change in the
environment where they live. Some of the changes
are harmful to the organism or other organisms, whereas
others are helpful.
L.EC.06.41 -
Describe how human beings are part of the
ecosystem of the Earth and that human activity can
purposefully, or accidentally, alter the balance
in ecosystems.
L.EC.06.42 -
Predict possible consequences of overpopulation of
organisms, including humans, (for example: species
extinction, resource depletion, climate change,
pollution).
Discipline 4 Earth Science
Standard: Solid Earth
K-7 Standard E.SE: Develop an understanding of the properties
of earth materials and how those properties make materials
useful. Understand gradual and rapid changes in earth materials
and features of the surface of Earth. Understand magnetic
properties of Earth.
E.SE.E.1 -
Earth Materials- Earth materials that occur in
nature include rocks, minerals, soils, water, and the gases
of the atmosphere. Some Earth materials have properties
which sustain plant and animal life.
E.SE.00.11 -
Identify Earth materials (air, water, soil) that are used
to grow plants.
E.SE.01.12 -
Describe how Earth materials contribute to the growth of
plant and animal life.
E.SE.03.13 -
Recognize and describe different types of earth materials
(mineral, rock, clay, boulder, gravel, sand, soil).
E.SE.03.14 -
Recognize that rocks are made up of minerals.
E.SE.E.2 -
Surface Changes- The surface of Earth changes.
Some changes are due to slow processes, such as erosion
and weathering, and some changes are due to rapid
processes, such as landslides, volcanic eruptions, and
earthquakes.
E.SE.02.21 -
Describe the major landforms of the surface of the
Earth (mountains, plains, plateaus, valleys, hills).
E.SE.03.22 -
Identify and describe natural causes of change in the
Earth’s surface (erosion, glaciers, volcanoes, landslides,
and earthquakes).
E.SE.E.3 -
Using Earth Materials- Some Earth materials have
properties that make them useful either in their present form
or designed and modified to solve human problems. They can
enhance the quality of life as in the case of materials used for
building or fuels used for heating and transportation.
E.SE.03.31 -
Identify Earth materials used to construct some common
objects (for example: bricks, buildings, roads, glass).
E.SE.03.32 -
Describe how materials taken from the Earth can be used
as fuels for heating and transportation.
E.SE.M.1 -
Soil- Soils consist of weathered rocks and
decomposed organic materials from dead plants, animals,
and bacteria. Soils are often found in layers with each
having a different chemical composition and texture.
E.SE.06.11 -
Explain how physical and chemical weathering lead to
erosion and the formation of soils and sediments.
E.SE.06.12 -
Explain how waves, wind, water, and glacier
movement, shape and reshape the land surface
of the Earth by eroding rock in some areas and
depositing sediments in other areas.
E.SE.06.13 -
Describe how soil is a mixture, made up of weather
eroded rock and decomposed organic material.
E.SE.06.14 -
Compare different soil samples based on particle size
and texture.
E.SE.M.4 -
Rock Formation- Rocks and rock formations bear
evidence of the minerals, materials, temperature/pressure
conditions, and forces that created them.
E.SE.06.41 -
Compare and contrast the formation of rock types
(igneous, metamorphic, and sedimentary) and
demonstrate the similarities and differences using
the rock cycle model.
E.SE.M.5 -
Plate Tectonics- The lithospheric plates of the Earth
constantly move, resulting in major geological events, such as
earthquakes, volcanic eruptions, and mountain building.
E.SE.06.51 -
Explain plate tectonic movement and how the
lithospheric plates move centimeters each year.
E.SE.06.52 -
Demonstrate how major geological events
(earthquakes, volcanic eruptions, mountain building)
result from these plate motions.
E.SE.06.53 -
Describe layers of the Earth as a lithosphere (crust and
upper mantle), convecting mantle, and dense metallic
core.
E.SE.M.6 -
Magnetic Field of Earth- Earth as a whole has
a magnetic field that is detectable at the surface with a
compass.
E.SE.06.61 -
Describe the Earth as a magnet and compare the
magnetic properties of the Earth to that of a natural or
man-made magnet.
E.SE.06.62 -
Explain how a compass works using the magnetic field of
the Earth, and how a compass is used for navigation on
land and sea.
Standard: Earth Systems
K-7 Standard E.ES: Develop an understanding of the warming of the
Earth by the sun as the major source of energy for phenomenon
on Earth and how the sun’s warming relates to weather, climate,
seasons, and the water cycle. Understand how human interaction
and use of natural resources affects the environment.
E.ES.E.1 -
Solar Energy- The sun warms the land, air and water
and helps plants grow.
E.ES.01.11 -
Identify the sun as the most important source of heat which
warms the land, air, and water of the Earth.
E.ES.01.12 -
Demonstrate the importance of sunlight and warmth in plant
growth.
E.ES.E.2 -
Weather- Weather changes from day to day and over the
seasons.
E.ES.01.21 -
Compare daily changes in the weather related to
temperature (cold, hot, warm, cool); cloud cover
(cloudy, partly cloudy, foggy) precipitation (rain, snow,
hail, freezing rain); wind (breezy, windy, calm).
E.ES.01.22 -
Describe and compare weather related to the four
seasons in terms of temperature, cloud cover,
precipitation, and wind.
E.ES.01.23 -
Describe severe weather events.
E.ES.01.24 -
Describe precautions that should be taken for human safety
during severe weather conditions (thunderstorms, lightning,
tornadoes, high winds, blizzards, hurricanes).
E.ES.E.3 -
Weather Measurement- Scientists use tools for
observing, recording, and predicting weather changes.
E.ES.01.31 -
Identify the tools that might be used to measure
temperature, precipitation, cloud cover and wind.
E.ES.01.32 -
Observe and collect data of weather conditions over a period
of time.
E.ES.E.4 -
Natural Resources- The supply of many natural
resources is limited. Humans have devised methods for
extending their use of natural resources through
recycling, reuse, and renewal.
E.ES.03.41 -
Identify natural resources (metals, fuels, fresh water,
farmland, and forests).
E.ES.03.42 -
Classify renewable (fresh water, farmland, forests) and
non-renewable (fuels, metals) resources.
E.ES.03.43 -
Describe ways humans are protecting, extending, and
restoring resources (recycle, reuse, reduce, renewal).
E.ES.03.44 -
Recognize that paper, metal, glass, and some plastics
can be recycled.
E.ES.E.5 -
Human Impact- Humans depend on their natural
and constructed environment. Humans change
environments in ways that are helpful or harmful for
themselves and other organisms.
E.ES.03.51 -
Describe ways humans are dependent on the natural
environment (forests, water, clean air, earth materials)
and constructed environments (homes, neighborhoods,
shopping malls, factories, and industry).
E.ES.03.52 -
Describe helpful or harmful effects of humans on the
environment (garbage, habitat destruction, land
management, renewable and non-renewable resources).
E.ES.M.6 -
Seasons- Seasons result from annual variations in
the intensity of sunlight and length of day due to the tilt of
the axis of the Earth relative to the plane of its yearly
orbit around the sun.
E.ES.05.61 -
Demonstrate using a model, seasons as the result of
variations in the intensity of sunlight caused by the tilt
of the Earth on its axis, and revolution around the sun.
E.ES.05.62 -
Explain how the revolution of the Earth around the
sun defines a year.
E.ES.M.1 -
Solar Energy- The sun is the major source of
energy for phenomena on the surface of the Earth.
E.ES.07.11 -
Demonstrate, using a model or drawing, the
relationship between the warming by the sun of the
Earth and the water cycle as it applies to the
atmosphere (evaporation, water vapor, warm air
rising, cooling, condensation, clouds).
E.ES.07.12 -
Describe the relationship between the warming of the
atmosphere of the Earth by the sun and convection
within the atmosphere and oceans.
E.ES.07.13 -
Describe how the warming of the Earth by the sun
produces winds and ocean currents.
E.ES.M.4 -
Human Consequences- Human activities have
changed the land, oceans, and atmosphere of the Earth
resulting in the reduction of the number and variety of wild
plants and animals sometimes causing extinction of species.
E.ES.07.41 -
Explain how human activities (surface mining,
deforestation, overpopulation, construction and urban
development, farming, dams, landfills, and restoring
natural areas) change the surface of the Earth and
affect the survival of organisms.
E.ES.07.42 -
Describe the origins of pollution in the atmosphere,
geosphere, and hydrosphere, (car exhaust, industrial
emissions, acid rain, and natural sources), and how
pollution impacts habitats, climatic change, threatens
or endangers species.
E.ES.M.7 -
Weather and Climate- Global patterns of
atmospheric and oceanic movement influence weather and
climate.
E.ES.07.71 -
Compare and contrast the difference and relationship
between climate and weather.
E.ES.07.72 -
Describe how different weather occurs due to the
constant motion of the atmosphere from the energy
of the sun reaching the surface of the Earth.
E.ES.07.73 -
Explain how the temperature of the oceans affects
the different climates on Earth because water in the
oceans holds a large amount of heat.
E.ES.07.74 -
Describe weather conditions associated with frontal
boundaries (cold, warm, stationary, and occluded) and
the movement of major air masses and the jet stream
across North America using a weather map.
E.ES.M.8 -
Water Cycle- Water circulates through the four spheres
of the Earth in what is known as the “water cycle.”
E.ES.07.81 -
Explain the water cycle and describe how evaporation,
transpiration, condensation, cloud formation,
precipitation, infiltration, surface runoff, ground water,
and absorption occur within the cycle.
E.ES.07.82 -
Analyze the flow of water between the components
of a watershed, including surface features (lakes,
streams, rivers, wetlands) and groundwater.
Standard: Fluid Earth
K-7 Standard E.FE: Develop an understanding that Earth is a
planet nearly covered with water and that water on Earth can be
found in three states, solid, liquid, and gas. Understand how water
on Earth moves in predictable patterns. Understand Earth’s
atmosphere as a mixture of gases and water vapor.
E.FE.E.1 -
Water- Water is a natural resource and is found
under the ground, on the surface of the earth, and in the
sky. It exists in three states (liquid, solid, gas) and can go
back and forth from one form to another.
E.FE.02.11 -
Identify water sources (wells, springs, lakes, rivers,
oceans).
E.FE.02.12 -
Identify household uses of water (drinking, cleaning,
food preparation).
E.FE.02.13 -
Describe the properties (visible, flowing, melting,
dew) of water as a liquid (lakes, rivers, streams,
oceans).
E.FE.02.14 -
Describe the properties (hard, visible, freezing, ice)
of water as a solid (ice, snow, iceberg, sleet, hail).
E.FE.E.2 -
Water Movement- Water moves in predictable
patterns.
E.FE.02.21 -
Describe how rain collects on the surface of the Earth
and flows downhill into bodies of water (streams,
rivers, lakes, oceans) or into the ground.
E.FE.02.22 -
Describe the major bodies of water on the Earth’s
surface (lakes, ponds, oceans, rivers, streams).
E.FE.M.1 -
Atmosphere- The atmosphere is a mixture of
nitrogen, oxygen and trace gases that include water vapor.
The atmosphere has different physical and chemical
composition at different elevations.
E.FE.07.11 -
Describe the atmosphere as a mixture of gases.
E.FE.07.12 -
Compare and contrast the composition of the
atmosphere at different elevations.
Standard: Earth in Space and Time
K-7 Standard E.ST: Develop an understanding that the sun is the central and
largest body in the solar system and that Earth and other objects in the sky move
in a regular and predictable motion around the sun. Understand that those
motions explain the day, year, moon phases, eclipses and the appearance of
motion of objects across the sky. Understand that gravity is the force that keeps
the planets in orbit around the sun and governs motion in the solar system.
Develop an understanding that fossils and layers of Earth provide evidence of the
history of Earth’s life forms, changes over long periods of time, and theories
regarding Earth’s history and continental drift.
E.ST.E.1 -
Characteristics of Objects in the Sky- Common
objects in the sky have observable characteristics.
E.ST.04.11 -
Identify common objects in the sky, such as the sun
and the moon.
E.ST.04.12 -
Compare and contrast the characteristics of the sun,
moon and Earth, including relative distances and
abilities to support life.
E.ST.E.2 -
Patterns of Objects in the Sky- Common objects in the
sky have observable characteristics and predictable
patterns of movement.
E.ST.04.21 -
Describe the orbit of the Earth around the sun as it
defines a year.
E.ST.04.22 -
Explain that the spin of the Earth creates day and
night.
E.ST.04.23 -
Describe the motion of the moon around the Earth.
E.ST.04.24 -
Explain how the visible shape of the moon follows a
predictable cycle which takes approximately one month.
E.ST.04.25 -
Describe the apparent movement of the sun and
moon across the sky through day/night and the
seasons.
E.ST.E.3 -
Fossils- Fossils provide evidence about the plants and
animals that lived long ago and the nature of the environment at that
time.
E.ST.04.31 -
Explain how fossils provide evidence of the history of the Earth.
E.ST.04.32 -
Compare and contrast life forms found in fossils and
organisms that exist today.
E.ST.M.1 -
Solar System- The sun is the central and
largest body in our solar system. Earth is the third planet
from the sun in a system that includes other planets and
their moons, as well as smaller objects, such as asteroids
and comets.
E.ST.05.11 -
Design a model that describes the position and
relationship of the planets and other objects (comets
and asteroids) to the sun.
E.ST.M.2 -
Solar System Motion- Gravity is the force that
keeps most objects in the solar system in regular and
predictable motion.
E.ST.05.21 -
Describe the motion of planets and moons in terms
of rotation on axis and orbits due to gravity.
E.ST.05.22 -
Explain moon phases as they relate to the position of
the moon in its orbit around the Earth, resulting in the
amount of observable reflected light.
E.ST.05.23 -
Recognize that nighttime objects (stars and
constellations) and the sun appear to move because
the Earth rotates on its axis and orbits the sun.
E.ST.05.24 -
Explain lunar and solar eclipses based on the relative
positions of the Earth, moon, and sun, and the orbit of
the moon.
E.ST.05.25 -
Explain the tides of the oceans as they relate to the
gravitational pull and orbit of the moon.
E.ST.M.3 -
Fossils- Fossils provide important evidence of how
life and environmental conditions have changed in a given
location.
E.ST.06.31 -
Explain how rocks and fossils are used to understand the
age and geological history of the earth (timelines and
relative dating, rock layers).
E.ST.M.4 -
Geologic Time- Earth processes seen today (erosion,
mountain building, and glacier movement) make possible
the measurement of geologic time through methods such as
observing rock sequences and using fossils to correlate the
sequences at various locations.
E.ST.06.41 -
Explain how Earth processes (erosion, mountain building,
and glacier movement) are used for the measurement of
geologic time through observing rock layers.
E.ST.06.42 -
Describe how fossils provide important evidence of how
life and environmental conditions have changed.
|
|
