Utah
Elementary Science Core Curriculum
Fourth
Grade
Adopted
by Utah State Board of Education
March
12, 2002
Science
is a way of knowing, a process for gaining knowledge and understanding of the
natural world. The Science Core Curriculum places emphasis on understanding and
using skills. Students should be active learners. It is not enough for students
to read about science; they must do science. They should observe, inquire,
question, formulate and test hypotheses, analyze data, report, and evaluate
findings. The students, as scientists, should have hands–on, active experiences
throughout the instruction of the science curriculum.
The
Elementary Science Core describes what students should know and be able to do at
the end of each of the K–6 grade levels. It was developed, critiqued, piloted,
and revised by a community of Utah science teachers, university science
educators, State Office of Education specialists, scientists, expert national
consultants, and an advisory committee representing a wide variety of people
from the community. The Core
reflects the current philosophy of science education that is expressed in
national documents developed by the American Association for the Advancement of
Science, the National Academies of Science. This Science Core has the endorsement of
the Utah Science Teachers Association.
The Core reflects high standards of achievement in science for all
students.
The
Core is designed to help teachers organize and deliver instruction.
The
Science Core Curriculum’s organization:
ü
Each
grade level begins with a brief course description.
ü
The
INTENDED LEARNING OUTCOMES (ILOs) describe the goals for science skills and
attitudes. They are found at the
beginning of each grade, and are an integral part of the Core that should be
included as part of instruction.
ü
The
SCIENCE BENCHMARKS describe the science content students should know. Each grade level has three to five
Science Benchmarks. The ILOs and
Benchmarks intersect in the Standards, Objectives and Indicators.
ü
A
STANDARD is a broad statement of what students are expected to understand.
Several Objectives are listed under each Standard.
ü
An
OBJECTIVE is a more focused description of what students need to know and be
able to do at the completion of instruction. If students have mastered the
Objectives associated with a given Standard, they are judged to have mastered
that Standard at that grade level. Several Indicators are described for each
Objective.
ü
An
INDICATOR is a measurable or observable student action that enables one to judge
whether a student has mastered a particular Objective. Indicators are not meant
to be classroom activities, but they can help guide classroom instruction.
Eight
Guidelines Were Used in Developing the Elementary Science
Core
Reflects
the Nature of Science: Science
is a way of knowing, a process of gaining knowledge and understanding of the
natural world. The Core is designed to produce an integrated set of Intended
Learning Outcomes (ILOs) for students. Please see the Intended Learning Outcomes
document for each grade level core.
As
described in these ILOs, students will:
1.
Use
science process and thinking skills.
2.
Manifest
science interests and attitudes.
3.
Understand
important science concepts and principles.
4.
Communicate
effectively using science language and reasoning.
5.
Demonstrate
awareness of the social and historical aspects of science.
6.
Understand
the nature of science.
Coherent:
The Core has been designed so that, wherever possible, the science ideas
taught within a particular grade level have a logical and natural
connection with each other and with those of earlier grades. Efforts have also
been made to select topics and skills that integrate well with one another and
with other subject areas appropriate to grade level. In addition, there is an
upward articulation of science concepts, skills, and content. This spiraling is intended to prepare
students to understand and use more complex science concepts and skills as they
advance through their science learning.
Developmentally
Appropriate: The Core takes into account the
psychological and social readiness of students. It builds from concrete
experiences to more abstract understandings. The Core describes science language
students should use that is appropriate to each grade level. A more extensive vocabulary should not
be emphasized. In the past, many
educators may have mistakenly thought that students understood abstract concepts
(such as the nature of the atom), because they repeated appropriate names and
vocabulary (such as electron and neutron). The Core resists the temptation to
tell about abstract concepts at inappropriate grade levels, but focuses on
providing experiences with concepts that students can explore and understand in
depth to build a foundation for future science learning.
Encourages
Good Teaching Practices:
It
is impossible to accomplish the full intent of the Core by lecturing and having
students read from textbooks. The Elementary Science Core emphasizes student
inquiry. Science process skills are central in each standard. Good science encourages students to gain
knowledge by doing science: observing, questioning, exploring, making and
testing hypotheses, comparing predictions, evaluating data, and communicating
conclusions. The Core is designed to encourage instruction with students working
in cooperative groups. Instruction
should connect lessons with students’ daily lives. The Core directs experiential
science instruction for all students, not just those who have traditionally
succeeded in science classes. The vignettes listed on the “Utah Science Home
Page” at http://www.usoe.k12.ut.us/curr/science
for each of the Core standards provide examples, based on actual practice, that
demonstrate that excellent teaching of the Science Core is
possible.
Comprehensive: The
Elementary Science Core does not cover all topics that have traditionally been
in the elementary science curriculum; however, it does provide a comprehensive
background in science. By emphasizing depth rather than breadth, the Core seeks
to empower students rather than intimidate them with a collection of isolated
and eminently forgettable facts. Teachers are free to add related concepts and
skills, but they are expected to teach all the standards and objectives
specified in the Core for their grade level.
Feasible:
Teachers and others who are familiar with
Utah students, classrooms, teachers, and schools have designed the Core. It can be taught with easily obtained
resources and materials. A Teacher Resource Book (TRB) is available for
elementary grades and has sample lessons on each topic for each grade level. The
TRB is a document that will grow as teachers add exemplary lessons aligned with
the new Core. The middle grade
levels have electronic textbooks available at the Utah State Office of
Education’s “Utah Science Home Page” at http://www.usoe.k12.ut.us/curr/science.
Useful
and Relevant: This
curriculum relates directly to student needs and interests. It is grounded in
the natural world in which we live. Relevance of science to other endeavors
enables students to transfer skills gained from science instruction into their
other school subjects and into their lives outside the
classroom.
Encourages
Good Assessment Practices:
Student achievement of the standards and objectives in this Core are best
assessed using a variety of assessment instruments. One’s purpose should be
clearly in mind as assessment is planned and implemented. Performance tests are
particularly appropriate to evaluate student mastery of science processes and
problem-solving skills. Teachers should use a variety of classroom assessment
approaches in conjunction with standard assessment instruments to inform their
instruction. Sample test items, keyed to each Core Standard, may be located on
the Utah Science Home Page. Observation of students engaged in science
activities is highly recommended as a way to assess students’ skills as well as
attitudes in science. The nature of
the questions posed by students provides important evidence of students’
understanding of science.
Elementary
school reaches the greatest number of students for a longer period of time
during the most formative years of the school experience. Effective elementary
science instruction engages students actively in enjoyable learning
experiences. Science instruction
should be as thrilling an experience for a child as seeing a rainbow, growing a
flower, or holding a toad. Science is not just for those who have traditionally
succeeded in the subject, and it is not just for those who will choose
science–related careers. In a world of rapidly expanding knowledge and
technology, all students must gain the skills they will need to understand and
function responsibly and successfully in the world. The Core provides skills in
a context that enables students to experience the joy of doing
science.
Fourth Grade Science Core
Curriculum
The theme for the fourth
grade Science Core curriculum is Utah natural history. Students will learn about Utah
environments including; weather, water cycle, rocks, fossils, soils, plants and
animals. Understanding the concepts
of cycles is an essential component of science literacy and is introduced
at this grade level. Emphasis
should be placed on skills to classify many things. Students should come to
value and use science as a process of obtaining knowledge based on observable
evidence, and their curiosity should be encouraged and sustained as they develop
the abilities associated with inquiry in science.
Good science instruction
requires that attention be paid to providing students with hands–on science
investigations in which student inquiry is an important goal. Their curiosity should be encouraged and
sustained. Teachers should provide opportunities for all students to experience
many things. Fourth graders should feel the excitement of a rainstorm, hunt for
fossils in rocks, observe the patterns in a spider web, and teach their parents
to recognize the song of the lark. They should have many opportunities to
observe and predict, to infer and to classify. They should come to enjoy science
as a process of learning about their world.
Science Core concepts should
be integrated with concepts and skills from other curriculum areas. Reading,
writing and mathematics skills should be emphasized as integral to the
instruction of science. Technology
issues and the nature of science are significant components of this Core. Personal relevance of science in
students’ lives is always an important part of helping students to value science
and should be emphasized at this grade-level.
This Core was designed using
the American Association for the Advancement of Science’s Project 2061:
Benchmarks For Science Literacy and the National Academy of Science’s
National Science Education Standards as guides to determine appropriate
content and skills.
The
fourth grade Science Core has three online resources designed to help with
classroom instruction; they include Teacher Resource Book –a set of
lesson plans, assessment items and science information specific to fourth grade;
the Sci-ber Text –an electronic science text book specific to the Utah
Core; and the science test item pool.
This pool includes multiple-choice questions, performance tasks, and
interpretive items aligned to the standards and objectives of the fourth grade
Science Core. These resources are
all available on the Utah Science Home Page. http://www.usoe.k12.ut.us/curr/science
SAFETY
PRECAUTIONS:
The
hands–on nature of this science curriculum increases the need for teachers to
use appropriate precautions in the classroom and field. Teachers must adhere to
the published guidelines for the proper use of animals, equipment, and chemicals
in the classroom. These guidelines
are available on the Utah Science Home Page.
Intended Learning Outcomes
for Fourth Grade Science
The
Intended Learning Outcomes (ILOs) describe the skills and attitudes students
should learn as a result of science instruction. They are an essential part of the
Science Core Curriculum and provide teachers with a standard for evaluation of
student learning in science.
Instruction should include significant science experiences that lead to
student understanding using the ILOs.
The main intent of science
instruction in Utah is that students will value and use science as a process of
obtaining knowledge based upon observable evidence.
By
the end of fourth grade students will be able to:
1. Use Science Process and Thinking
Skills
2. Manifest Scientific Attitudes and
Interests
3. Understand Science Concepts and
Principles
4. Communicate Effectively Using Science
Language and Reasoning
Science
Benchmark
Matter on Earth cycles from
one form to another. The cycling of
matter on Earth requires energy.
The cycling of water is an example of this process. The sun is the source of energy for the
water cycle. Water changes state as
it cycles between the atmosphere, land, and bodies of water on
Earth.
STANDARD
I: Students will understand that
water changes state as it moves through the water
cycle.
Objective
1: Describe the relationship between heat
energy, evaporation and condensation of water on Earth.
a.
Identify
the relative amount and kind of water found in various locations on Earth (e.g.,
oceans have most of the water, glaciers and snowfields contain most fresh
water).
b.
Identify
the sun as the source of energy that evaporates water from the surface of
Earth.
c.
Compare
the processes of evaporation and condensation of water.
d.
Investigate
and record temperature data to show the effects of heat energy on changing the
states of water.
Objective
2: Describe the water
cycle.
a.
Locate
examples of evaporation and condensation in the water cycle (e.g., water
evaporates when heated and clouds or dew forms when vapor is
cooled).
b.
Describe
the processes of evaporation, condensation, and precipitation as they relate to
the water cycle.
c.
Identify
locations that hold water as it passes through the water cycle (e.g., oceans,
atmosphere, fresh surface water, snow, ice, and ground
water).
d.
Construct
a model or diagram to show how water continuously moves through the water cycle
over time.
e.
Describe
how the water cycle relates to the water supply in your
community.
|
Science
language students should use: |
vapor,
precipitation, evaporation, clouds, dew, condensation, temperature, water
cycle |
Science
Benchmark
Weather
describes conditions in the atmosphere at a certain place and time. Water, energy from the sun, and wind
create a cycle of changing weather.
The sun's energy warms the oceans and lands at Earth's surface, creating
changes in the atmosphere that cause the weather. The temperature and movement of air can
be observed and measured to determine the effect on cloud formation and
precipitation. Recording weather
observations provides data that can be used to predict future weather conditions
and establish patterns over time.
Weather affects many aspects of people's
lives.
STANDARD
II: Students will understand that
the elements of weather can be observed, measured, and recorded to make
predictions and determine simple weather patterns.
Objective
1: Observe, measure, and record the basic
elements of weather.
a.
Identify
basic cloud types (i.e., cumulus, cirrus, stratus clouds).
b.
Observe,
measure, and record data on the basic elements of weather over a period of time
(i.e., precipitation, air temperature, wind speed and direction, and air
pressure).
c.
Investigate
evidence that air is a substance (e.g., takes up space, moves as wind,
temperature can be measured).
d.
Compare
the components of severe weather phenomena to normal weather conditions (e.g.,
thunderstorm with lightning and high winds compared to rainstorm with rain
showers and breezes).
Objective
2: Interpret recorded weather data for
simple patterns.
a.
Observe
and record effects of air temperature on precipitation (e.g., below freezing
results in snow, above freezing results in rain).
b.
Graph
recorded data to show daily and seasonal patterns in
weather.
c.
Infer
relationships between wind and weather change (e.g., windy days often precede
changes in the weather; south winds in Utah often precede a cold front coming
from the north).
Objective
3: Evaluate weather predictions based upon
observational data.
a.
Identify
and use the tools of a meteorologist (e.g., measure rainfall using rain gage,
measure air pressure using barometer, measure temperature using a
thermometer).
b.
Describe
how weather and forecasts affect people's lives.
c.
Predict
weather and justify prediction with observable evidence.
d.
Evaluate
the accuracy of student and professional weather
forecasts.
e.
Relate
weather forecast accuracy to evidence or tools used to make the forecast (e.g.,
feels like rain vs. barometer is dropping).
|
Science
language students should use: |
atmosphere,
meteorologist, freezing, cumulus, stratus, cirrus, air pressure,
thermometer, air temperature, wind speed, forecast, severe, phenomena,
precipitation, seasonal, accuracy, barometer, rain gauge,
components |
Science
Benchmark
Earth
materials include rocks, soils, water, and gases. Rock is composed of minerals. Earth materials change over time from
one form to another. These changes
require energy. Erosion is the
movement of materials and weathering is the breakage of bedrock and larger rocks
into smaller rocks and soil materials.
Soil is continually being formed from weathered rock and plant
remains. Soil contains many living
organisms. Plants generally get
water and minerals from soil.
STANDARD
III: Students will understand the
basic properties of rocks, the processes involved in the formation of soils, and
the needs of plants provided by soil.
Objective
1: Identify basic properties of minerals
and rocks.
a.
Describe
the differences between minerals and rocks.
b.
Observe
rocks using a magnifying glass and draw shapes and colors of the
minerals.
c.
Sort
rocks by appearance according to the three basic types: sedimentary, igneous and
metamorphic (e.g., sedimentary–rounded-appearing mineral and rock particles that
are cemented together, often in layers; igneous–with or without observable
crystals that are not in layers or with or without air holes or glasslike;
metamorphic –crystals/minerals, often in layers).
d.
Classify
common rocks found in Utah as sedimentary (i.e., sandstone, conglomerate,
shale), igneous (i.e., basalt, granite, obsidian, pumice) and metamorphic (i.e.,
marble, gneiss, schist).
Objective
2: Explain how the processes of weathering
and erosion change and move materials that become soil.
a.
Identify
the processes of physical weathering that break down rocks at Earth's surface
(i.e., water movement, freezing, plant growth, wind).
b.
Distinguish
between weathering (i.e., wearing down and breaking of rock surfaces) and
erosion (i.e., the movement of materials).
c.
Model
erosion of Earth materials and collection of these materials as part of the
process that leads to soil (e.g., water moving sand in a playground area and
depositing this sand in another area).
d.
Investigate
layers of soil in the local area and predict the sources of the sand and rocks
in the soil.
Objective
3: Observe the basic components of soil and
relate the components to plant growth.
a.
Observe
and list the components of soil (i.e., minerals, rocks, air, water, living and
dead organisms) and distinguish between the living, nonliving, and once living
components of soil.
b.
Diagram
or model a soil profile showing topsoil, subsoil, and bedrock, and how the
layers differ in composition.
c.
Relate
the components of soils to the growth of plants in soil (e.g., mineral
nutrients, water).
d.
Explain
how plants may help control the erosion of soil.
e.
Research
and investigate ways to provide mineral nutrients for plants to grow without
soil (e.g., grow plants in wet towels, grow plants in wet gravel, grow plants in
water).
|
Science
language students should use: |
mineral,
weathering, erosion, sedimentary, igneous, metamorphic, topsoil, subsoil,
bedrock, organism, freeze, thaw, profile, nonliving, structural support,
nutrients |
Science
Benchmark
Fossils
are evidence of living organisms from the past and are usually preserved in
sedimentary rocks. A fossil may be
an impression left in sediments, the preserved remains of an organism, or a
trace mark showing that an organism once existed. Fossils are usually made from the hard
parts of an organism because soft parts decay quickly. Fossils provide clues to Earth's
history. They provide evidence that
can be used to make inferences about past environments. Fossils can be compared to one another,
to living organisms, and to organisms that lived long
ago.
STANDARD
IV: Students will understand how
fossils are formed, where they may be found in Utah, and how they can be used to
make inferences.
Objective
1: Describe Utah fossils and explain how
they were formed.
a.
Identify
features of fossils that can be used to compare them to living organisms that
are familiar (e.g., shape, size and structure of skeleton, patterns of
leaves).
b.
Describe
three ways fossils are formed in sedimentary rock (i.e., preserved organisms,
mineral replacement of organisms, impressions or tracks).
c.
Research
locations where fossils are found in Utah and construct a simple fossil
map.
Objective
2: Explain how fossils can be used to make
inferences about past life, climate, geology, and
environments.
a.
Explain
why fossils are usually found in sedimentary rock.
b.
Based
on the fossils found in various locations, infer how Utah environments have
changed over time (e.g., trilobite fossils indicate that Millard County was once
covered by a large shallow ocean; dinosaur fossils and coal indicate that Emery
and Uintah County were once tropical and swampy).
c.
Research
information on two scientific explanations for the extinction of dinosaurs and
other prehistoric organisms.
d.
Formulate
questions that can be answered using information gathered on the extinction of
dinosaurs.
|
Science
language students should use: |
infer,
environments, climate, dinosaur, preserved, extinct, extinction,
impression, fossil, prehistoric, mineral, organism, replacement,
trilobite, sedimentary, tropical |
Science
Benchmark
Utah
has diverse plant and animal life that is adapted to and interacts in areas that
can be described as wetlands, forests, and deserts. The characteristics of the
wetlands, forests, and deserts influence which plants and animals survive best
there. Living and nonliving things
in these areas are classified based on physical
features.
STANDARD
V: Students will understand the
physical characteristics of Utah's wetlands, forests, and deserts and identify
common organisms for each environment.
Objective
1: Describe the physical characteristics of
Utah's wetlands, forests, and deserts.
a.
Compare
the physical characteristics (e.g., precipitation, temperature, and surface
terrain) of Utah's wetlands, forests, and deserts.
b.
Describe
Utah’s wetlands (e.g., river, lake, stream, and marsh areas where water is a
major feature of the environment) forests (e.g., oak, pine, aspen, juniper areas
where trees are a major feature of the environment), and deserts (e.g., areas
where the lack of water provided an environment where plants needing little
water are a major feature of the environment).
c.
Locate
examples of areas that have characteristics of wetlands, forests, or deserts in
Utah.
d.
Based
upon information gathered, classify areas of Utah that are generally identified
as wetlands, forests, or deserts.
e.
Create
models of wetlands, forests, and deserts.
Objective
2: Describe the common plants and animals
found in Utah environments and how these organisms have adapted to the
environment in which they live.
a.
Identify
common plants and animals that inhabit Utah's forests, wetlands, and
deserts.
b.
Cite
examples of physical features that allow particular plants and animals to live
in specific environments (e.g., duck has webbed feet, cactus has waxy
coating).
c.
Describe
some of the interactions between animals and plants of a given environment
(e.g., woodpecker eats insects that live on trees of a forest, brine shrimp of
the Great Salt Lake eat algae and birds feed on brine
shrimp).
d.
Identify
the effect elevation has on types of plants and animals that live in a specific
wetland, forest, or desert.
e.
Find
examples of endangered Utah plants and animals and describe steps being taken to
protect them.
Objective
3: Use a simple scheme to classify Utah
plants and animals.
a.
Explain
how scientists use classification schemes.
b.
Use
a simple classification system to classify unfamiliar Utah plants or animals
(e.g., fish/amphibians/reptile/bird/mammal, invertebrate/vertebrate,
tree/shrub/grass, deciduous/conifers).
Objective
4: Observe and record the behavior of Utah
animals.
a.
Observe
and record the behavior of birds (e.g., caring for young, obtaining food,
surviving winter).
b.
Describe
how the behavior and adaptations of Utah mammals help them survive winter (e.g.,
obtaining food, building homes, hibernation, migration).
c.
Research
and report on the behavior of a species of Utah fish (e.g., feeding on the
bottom or surface, time of year and movement of fish to spawn, types of food and
how it is obtained).
d.
Compare
the structure and behavior of Utah amphibians and
reptiles.
e.
Use
simple classification schemes to sort Utah's common insects and
spiders.
|
Science
language students should use: |
wetland,
forest, desert, adaptation, deciduous, coniferous, invertebrate,
vertebrate, bird, amphibian, reptile, fish, mammal, insect, hibernation,
migration |
|
Common
plants: |
sagebrush,
pinyon pine, Utah juniper, spruce, fir, oak brush, quaking aspen,
cottonwood, cattail, bulrush, prickly pear
cactus |
|
Common
animals: |
jackrabbit,
cottontail rabbit, red fox, coyote, mule deer, elk, moose, cougar, bobcat,
deer mouse, kangaroo rat, muskrat, beaver, gopher snake, rattlesnake,
lizard, tortoise, frog, salamander, red–tailed hawk, barn owl, lark,
robin, pinyon jay, magpie, crow, trout, catfish, carp, grasshopper, ant,
moth, butterfly, housefly, bee, wasp, pill bug,
millipede |