The Solar System

The activities we have selected are congruent with the Next Generation Science Standards (NGSS), and are arranged to build upon one another. Therefore, to follow the storyline we recommend that teachers complete the activities in the order provided. To open an activity in a new tab or window, right click the activity link and select the preferred option.

×

Evolution of Our Solar System: Time Lineup

View Activity
http://www.lpi.usra.edu/education/timeline/activity/

In this activity from the Universities Space Research Association (USRA) Lunar and Planetary Institute, learners work in groups or as a class to determine the order of events that formed our solar system.

Instructional Strategies: Inquiry, Challenge or problem-solving

Resource Type: Laboratory investigation, experiment or demonstration

Time Required: 45 minutes

Standards: ESS TEKS: 5.A, 5.D, 6.A, 6.B ES Literacy: 2.2, 2.3, 2.5, 2.6, 2.7, 3.4, 4., 6.3, 6.4, 6.5, 6.6, 6.7, 6.8

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

5.A analyze how gravitational condensation of solar nebular gas and dust can lead to the accretion of planetesimals and protoplanets
5.D explore the historical and current hypotheses for the origin of the Moon, including the collision of Earth with a Mars-sized planetesimal
6.A analyze the changes of Earth's atmosphere that could have occurred through time from the original hydrogen-helium atmosphere, the carbon dioxide-water vapor-methane atmosphere, and the current nitrogen-oxygen atmosphere
6.B evaluate the role of volcanic outgassing and impact of water-bearing comets in developing Earth's atmosphere and hydrosphere

Earth Science Literacy Principles

2.2 Our Solar System formed from a vast cloud of gas and dust 4.6 billion years ago.
2.3 Earth formed from the accumulation of dust and gas, and multiple collisions of smaller planetary bodies.
2.5 Studying other objects in the solar system helps us learn Earth’s history.
2.6 Life on Earth began more than 3.5 billion years ago.
2.7 Over Earth’s vast history, both gradual and catastrophic processes have produced enormous changes.
3.4 Earth’s systems interact over a wide range of temporal and spatial scales.
4. Earth is continuously changing.
6.3 Biological diversity, both past and present, is vast and largely undiscovered.
6.4 More complex life forms and ecosystems have arisen over the course of Earth’s history.
6.5 Microorganisms dominated Earth’s early biosphere and continue today to be the most widespread, abundant, and diverse group of organisms on the planet.
6.6 Mass extinctions occur when global conditions change faster than species in large numbers can adapt.
6.7 The particular life forms that exist today, including humans, are a unique result of the history of Earth’s systems.
6.8 Life changes the physical and chemical properties of Earth’s geosphere, hydrosphere, and atmosphere.

×

How Planets Form

View Activity
https://lasp.colorado.edu/outerplanets/solsys_planets.php

The University of Colorado at Boulder's Laboratory for Atmospheric and Space Physics (LASP) website outlines facts about terrestrial and Jovian planet formation with readings and interactive animations.

Instructional Strategies: Reading

Resource Type: Visualization (static visualization, animation, simulation)

Time Required: 15 minutes

Standards: ESS TEKS: 1.C, 2.E, 5.A, 5.E ES Literacy: 2.2, 2.3

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.C use the school's technology and information systems in a wise and ethical manner.
2.E demonstrate the use of course equipment, techniques, and procedures, including computers and web-based computer applications;
5.A analyze how gravitational condensation of solar nebular gas and dust can lead to the accretion of planetesimals and protoplanets
5.E compare terrestrial planets to gas-giant planets in the solar system, including structure, composition, size, density, orbit, surface features, tectonic activity, temperature, and suitability for life

Earth Science Literacy Principles

2.2 Our Solar System formed from a vast cloud of gas and dust 4.6 billion years ago.
2.3 Earth formed from the accumulation of dust and gas, and multiple collisions of smaller planetary bodies.

×

Modeling Planetary Interiors and Differentiation

View Activity
http://www.lpi.usra.edu/education/workshops/unknownMoon/Tuesday/Activity_Differentiation_Planetary_Interiors.pdf

In this activity from USRA's Lunar and Planetary Institute, learners model the interior structure of the terrestrial planets and the process of differentiation using solids and liquids of different densities.

Instructional Strategies: Inquiry

Resource Type: Laboratory investigation, experiment or demonstration

Time Required: 45 minutes

Standards: ESS TEKS: 1.A, 2.B, 2.E, 2.H, 3.A, 5.B, 5.E ES Literacy: 1.2, 1.3, 2.5

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.A demonstrate safe practices during laboratory and field investigations;
2.B know that scientific hypotheses are tentative and testable statements that must be capable of being supported or not supported by observational evidence. Hypotheses of durable explanatory power which have been tested over a wide variety of conditions are incorporated into theories;
2.E demonstrate the use of course equipment, techniques, and procedures, including computers and web-based computer applications;
2.H use mathematical procedures such as algebra, statistics, scientific notation, and significant figures to analyze data using the International System (SI) units
3.A in all fields of science, analyze, evaluate, and critique scientific explanations by using empirical evidence, logical reasoning, and experimental and observational testing, including examining all sides of scientific evidence of those scientific explanations, so as to encourage critical thinking by the student;
5.B investigate thermal energy sources, including kinetic heat of impact accretion, gravitational compression, and radioactive decay, which are thought to allow protoplanet differentiation into layers
5.E compare terrestrial planets to gas-giant planets in the solar system, including structure, composition, size, density, orbit, surface features, tectonic activity, temperature, and suitability for life

Earth Science Literacy Principles

1.2 Earth scientists use a large variety of scientific principles to understand how our planet works.
1.3 Earth science investigations take many different forms.
2.5 Studying other objects in the solar system helps us learn Earth’s history.

×

The Voyage Scale Model Solar System

View Activity
https://solarsystem.nasa.gov/resources/365/the-voyage-scale-model-solar-system/

In this activity from the Universities Space Research Association, students design a scale model of the Solar System illustrating the physical sizes of the sun and the planets and the distances between them.

Instructional Strategies: Modeling

Resource Type: Classroom learning activity

Time Required: 90 minutes

Standards: ESS TEKS: 1.A, 2.G, 2.H, 2.I, 3.A, 5.C, 5.E ES Literacy: 1.3

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.A demonstrate safe practices during laboratory and field investigations;
2.G organize, analyze, evaluate, make inferences, and predict trends from data;
2.H use mathematical procedures such as algebra, statistics, scientific notation, and significant figures to analyze data using the International System (SI) units
2.I communicate valid conclusions supported by data using several formats such as technical reports, lab reports, labeled drawings, graphic organizers, journals, presentations, and technical posters.
3.A in all fields of science, analyze, evaluate, and critique scientific explanations by using empirical evidence, logical reasoning, and experimental and observational testing, including examining all sides of scientific evidence of those scientific explanations, so as to encourage critical thinking by the student;
5.C contrast the characteristics of comets, asteroids, and meteoroids and their positions in the solar system, including the orbital regions of the terrestrial planets, the asteroid belt, gas giants, Kuiper Belt, and Oort Cloud
5.E compare terrestrial planets to gas-giant planets in the solar system, including structure, composition, size, density, orbit, surface features, tectonic activity, temperature, and suitability for life

Earth Science Literacy Principles

1.3 Earth science investigations take many different forms.

×

The Great Planetary Debate

View Activity
https://www.windows2universe.org/?page=/teacher_resources/planetary_debate_edu.html

In this activity, from Windows to the Universe, learners work cooperatively to conduct research, mount a debate, and practice communication and listening skills. This activity requires that students use computers for web-based research on planetary bodies.

Instructional Strategies: Debate

Resource Type: Classroom learning activity

Time Required: 300 minutes (research can be assigned as out of class work)

Standards: ESS TEKS: 3.B, 5.E ES Literacy: 1.2, 1.3, 2.5

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

3.B communicate and apply scientific information extracted from various sources such as current events, news reports, published journal articles, and marketing materials
5.E compare terrestrial planets to gas-giant planets in the solar system, including structure, composition, size, density, orbit, surface features, tectonic activity, temperature, and suitability for life

Earth Science Literacy Principles

1.2 Earth scientists use a large variety of scientific principles to understand how our planet works.
1.3 Earth science investigations take many different forms.
2.5 Studying other objects in the solar system helps us learn Earth’s history.

×

Jorge Salazar interview with Carol Raymond on Asteroid Vesta (2012)

View Activity
http://earthsky.org/space/carol-raymond-reveals-asteroid-vesta

In this interview with Carol Raymond, Deputy Principal Investigator of NASA's Dawn mission to orbit the massive asteroid Vesta, students learn about the first ever orbit of an asteroid.

Instructional Strategies: Reading

Resource Type: Interview with an expert

Time Required: 2 minutes

Standards: ESS TEKS: 1.C, 3.B, 5.C ES Literacy: 2.5

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.C use the school's technology and information systems in a wise and ethical manner.
3.B communicate and apply scientific information extracted from various sources such as current events, news reports, published journal articles, and marketing materials
5.C contrast the characteristics of comets, asteroids, and meteoroids and their positions in the solar system, including the orbital regions of the terrestrial planets, the asteroid belt, gas giants, Kuiper Belt, and Oort Cloud

Earth Science Literacy Principles

2.5 Studying other objects in the solar system helps us learn Earth’s history.

×

Kuiper Belt and Oort Cloud

View Activity
http://solarsystem.nasa.gov/planets/

NASA's Solar System Exploration website gives an overview of general information on the Kuiper Belt and Oort Cloud.

Instructional Strategies: Reading

Resource Type: News or popular magazine article

Time Required: 30 minutes

Standards: ESS TEKS: 1.C, 2.C, 5.C ES Literacy: 2.5

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.C use the school's technology and information systems in a wise and ethical manner.
2.C know that scientific theories are based on natural and physical phenomena and are capable of being tested by multiple independent researchers. Unlike hypotheses, scientific theories are well-established and highly-reliable explanations, but may be subject to change as new areas of science and new technologies are developed;
5.C contrast the characteristics of comets, asteroids, and meteoroids and their positions in the solar system, including the orbital regions of the terrestrial planets, the asteroid belt, gas giants, Kuiper Belt, and Oort Cloud

Earth Science Literacy Principles

2.5 Studying other objects in the solar system helps us learn Earth’s history.

×

Teaching tools: Comets and Asteroids

View Activity
http://amazing-space.stsci.edu/eds/tools/topic/comets.php.

This "Amazing Space" website from the Formal Education Group of the Space Telescope Science Institute's Office of Public Outreach contains a variety of online resources, explorations, and information on facts, myths, and legends regarding comets and asteroids.

Instructional Strategies: Modeling

Resource Type: Visualization (static visualization, animation, simulation)

Time Required: 30 minutes

Standards: ESS TEKS: 1.C, 5.C ES Literacy: 2.2

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.C use the school's technology and information systems in a wise and ethical manner.
5.C contrast the characteristics of comets, asteroids, and meteoroids and their positions in the solar system, including the orbital regions of the terrestrial planets, the asteroid belt, gas giants, Kuiper Belt, and Oort Cloud

Earth Science Literacy Principles

2.2 Our Solar System formed from a vast cloud of gas and dust 4.6 billion years ago.

×

Asteroids and Kuiper Belt Objects -- Resonance

View Activity
http://astro.unl.edu/vlabs/

In VLab 9, from the University of Nebraska-Lincoln, learners investigate the role of orbital resonance in differentiating the structure of the solar system.

Instructional Strategies: Inquiry

Resource Type: Laboratory investigation, experiment or demonstration

Time Required: 45 minutes

Standards: ESS TEKS: 1.C, 2.E, 2.H, 3.A, 5.C ES Literacy: 1.3

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.C use the school's technology and information systems in a wise and ethical manner.
2.E demonstrate the use of course equipment, techniques, and procedures, including computers and web-based computer applications;
2.H use mathematical procedures such as algebra, statistics, scientific notation, and significant figures to analyze data using the International System (SI) units
3.A in all fields of science, analyze, evaluate, and critique scientific explanations by using empirical evidence, logical reasoning, and experimental and observational testing, including examining all sides of scientific evidence of those scientific explanations, so as to encourage critical thinking by the student;
5.C contrast the characteristics of comets, asteroids, and meteoroids and their positions in the solar system, including the orbital regions of the terrestrial planets, the asteroid belt, gas giants, Kuiper Belt, and Oort Cloud

Earth Science Literacy Principles

1.3 Earth science investigations take many different forms.

×

Origin of the Earth and Moon

View Activity
http://solarsystem.nasa.gov/scitech/display.cfm?ST_ID=446

This article from NASA's "Solar System Exploration" site contains information discussing the theories for the formation of Earth's moon and the Solar System's planets.

Instructional Strategies: Reading

Resource Type: Scholarly article

Time Required: 30 minutes

Standards: ESS TEKS: 1.C, 2.I, 3.F, 5.A, 5.B, 5.D ES Literacy: 1., 2., 1.7, 2.2, 2.3

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.C use the school's technology and information systems in a wise and ethical manner.
2.I communicate valid conclusions supported by data using several formats such as technical reports, lab reports, labeled drawings, graphic organizers, journals, presentations, and technical posters.
3.F learn and understand the contributions of scientists to the historical development of Earth and space sciences
5.A analyze how gravitational condensation of solar nebular gas and dust can lead to the accretion of planetesimals and protoplanets
5.B investigate thermal energy sources, including kinetic heat of impact accretion, gravitational compression, and radioactive decay, which are thought to allow protoplanet differentiation into layers
5.D explore the historical and current hypotheses for the origin of the Moon, including the collision of Earth with a Mars-sized planetesimal

Earth Science Literacy Principles

1. Earth scientists use repeatable observations and testable ideas to understand and explain our planet.
2. Earth is 4.6 billion years old.
1.7 Technological advances, breakthroughs in interpretation, and new observations continuously refine our understanding of Earth.
2.2 Our Solar System formed from a vast cloud of gas and dust 4.6 billion years ago.
2.3 Earth formed from the accumulation of dust and gas, and multiple collisions of smaller planetary bodies.

×

NASA Moon Impact Crater Lab

View Activity
http://www.nasa.gov/pdf/180572main_ETM.Impact.Craters.pdf

In this lab students study the different features of an impact crater and test the different variables that influence a crater's size. They also construct explanations for their findings. This lab requires that teachers review the origin of craters and volcanoes on planetary bodies, including Earth.

Instructional Strategies: Inquiry, Modeling

Resource Type: Laboratory investigation, experiment or demonstration

Time Required: 90 minutes

Standards: ESS TEKS: 1.A, 2.G, 2.I, 5.C, 5.D ES Literacy: 2.5

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.A demonstrate safe practices during laboratory and field investigations;
2.G organize, analyze, evaluate, make inferences, and predict trends from data;
2.I communicate valid conclusions supported by data using several formats such as technical reports, lab reports, labeled drawings, graphic organizers, journals, presentations, and technical posters.
5.C contrast the characteristics of comets, asteroids, and meteoroids and their positions in the solar system, including the orbital regions of the terrestrial planets, the asteroid belt, gas giants, Kuiper Belt, and Oort Cloud
5.D explore the historical and current hypotheses for the origin of the Moon, including the collision of Earth with a Mars-sized planetesimal

Earth Science Literacy Principles

2.5 Studying other objects in the solar system helps us learn Earth’s history.

×

NASA Earthrise: The 45th Annniversary

View Activity
https://svs.gsfc.nasa.gov/cgi-bin/details.cgi?aid=4129

This short video is a wonderful reconstruction of how the classic photo of Earth rising above the moon was captured by Apollo 8. It is a testament to the emotional power of seeing the Earth as one world, our home, in Astronaut Jim Lovell's words, "a grand oasis in the vastness of space."

Instructional Strategies: Lecture

Resource Type: Video

Time Required: 7 minutes

Standards: ESS TEKS: 1.C, 2.E, 3.E, 3.F ES Literacy: 1., 2., 1.7

Hide

Texas Essential Knowledge and Skills for Science (TEKS) 112.36-- Earth and Space Science

1.C use the school's technology and information systems in a wise and ethical manner.
2.E demonstrate the use of course equipment, techniques, and procedures, including computers and web-based computer applications;
3.E explore careers and collaboration among scientists in Earth and space sciences
3.F learn and understand the contributions of scientists to the historical development of Earth and space sciences

Earth Science Literacy Principles

1. Earth scientists use repeatable observations and testable ideas to understand and explain our planet.
2. Earth is 4.6 billion years old.
1.7 Technological advances, breakthroughs in interpretation, and new observations continuously refine our understanding of Earth.

Field Trips

Studies that examine how geologists think and learn about the Earth point to the value of field experiences in helping students develop practices that constitute geologic reasoning. We encourage teachers to take students into the field as much as possible. The former recognizes the limitations of the K-12 classroom setting. Field learning provides a chance to encourage the ability to see features that are important to professional practice. Therefore, we include ideas for virtual and actual field trips. In the case of space exploration, teachers may be able to organize visits to a local science center, museum, college or university with planetarium and/or observatory facilities. Teachers can check with their own school district to see if they have access to a travelling planetarium.

Virtual Field Trips

NASA Small-Body Database browser

This Java applet generates an interactive diagram of the orbit of an asteroid or comet of the user's choice. Enter the formal name of the asteroid or comet (e.g. "1 Ceres" or 1P/Halley.)

Actual Field Trips

The University of Texas McDonald Observatory offers educational twilight programs and daily tours of its research telescopes.

Space Center Houston offers a variety of education programs and hosts school visits.

Scaffolding Notes

Teachers must develop their own individual plan for how they will teach the unit.The learning activities and educational resources in this unit are intended to complement other instructional activities led by the teacher. Many of the selected learning experiences provide links to excellent background preparatory materials, additional hands-on resources, teaching tips, and cross-curricular connections.

Teachers will need to create their own multimedia presentations, deliver lectures and assign ancillary work to their students in order to set the stage for effective use of the learning activities contained herein. Therefore, it is imperative to allocate time to review the activities and background material prior to using the learning experiences in this unit and to probe students for their prior knowledge before starting an activity.

In addition, although some activities may incorporate assessments, teachers may need to create their own assessments to ensure that are appropriate for the students they teach.

Asterisks (*) indicate teacher resource and background information recommendations for activity support.

_________________________________________________________

In Solar System Evolution–Time Lineup, students ages 12–17 work in groups or as a class to determine the order of the events that formed our solar system. This is an excellent activity to begin a discussion of these events and of the interrelated changes that have occurred within Earth's geosphere and biosphere through time.

The activity How Planets Form can be implemented in several different ways, such as using a jigsaw approach or learning stations.

Modeling Planetary Interiors and Differentiation has students work together as teams to create working models of the interiors of the terrestrial planets and the Moon using various materials. Teachers will need to gather materials prior to beginning the activity, including solid materials that are insoluble and of different densities as well as light-colored, non-toxic liquids of different densities.

For The Voyage Scale Model Solar System, it is recommended that teachers have scale models on hand to help explain the concept of calculating ratios in such models.

The Planetary Bodies of Our Solar System Debate requires that students use computers for web-based research on planetary bodies.

The Jorge Salazar interview with Carol Raymond on Asteroid Vesta is a 90-second podcast about the 2012 NASA mission to visit the asteroid Vesta. Instructors may wish to use guided questioning to review the origin of the solar system, introduce asteroids and the asteroid belt between the orbits of Mars and Jupiter, and consider and discuss the hazard posed by near-Earth asteroids. The page contains a link that shows a red-blue 3-D fly-by tour of the surface features of Vesta.

NASA's Kuiper Belt and Oort Cloud: Overview gives an overview of general information about these celestial regions. It may be assigned as a homework reading with teacher created-questions assigned. Teachers should lead a discussion to students' answers to these questions the following class period. The activity can also be used in class as a jigsaw or reading activity.

The Teaching Tools: Comets and Asteroids resource time is estimated at 20-30 minutes. It can be used as a reinforcing resource, an introductory lecture or to inform a teacher-directed classroom discussion.

*Orbital resonance is a property of the solar system that differentiates the planets, asteroid belt and Kuiper belt into distinct regions. The following activity demonstrates this property.

In Asteroids and Kuiper Belt Objects – Resonance, students input values for radial distance from the Sun - the semi-major axis - and the object's eccentricity to view the orbital relationship between it and Neptune, demonstrating that at certain distances several types of orbital resonance take place.

Origins of the Earth and Moon is an article containing information about the Big Impact theory regarding the creation of the Moon, the formation of the planets through accumulation in our solar system, and the calculated length of time it took for the planets to accrete.

The NASA Moon Impact Crater Lab requires that teachers review the origin of craters and volcanoes on planetary bodies, including Earth. Impact craters on planetary bodies resemble volcanic craters/calderas. This lab requires significant teacher prep, so be sure to read the teacher guide ahead of time, allowing plenty of time to gather necessary materials.