Massachusetts - Science: Grade 8

Seasons: Why do we have them?

Learn why the temperature in the summertime is higher than it is in the winter by studying the amount of light striking the Earth. Experiment with a plate detector to measure the amount of light striking the plate as the angle of the plate is adjusted (and then use a group of plates placed at different locations on the Earth) and measure the incoming radiation on each plate. 5 Minute Preview

Seasons in 3D

Gain an understanding of the causes of seasons by observing Earth as it orbits the Sun in three dimensions. Observe the path of the Sun across the sky on any date and from any location. Create graphs of solar intensity and day length, and use collected data to describe and explain seasonal changes. 5 Minute Preview

Seasons Around the World

Use a three dimensional view of the Earth, Moon and Sun to explore seasonal changes at a variety of locations. Strengthen your knowledge of global climate patterns by comparing solar energy input at the Poles to the Equator. Manipulate Earth's axis to increase or diminish seasonal changes. 5 Minute Preview

Seasons: Earth, Moon, and Sun

Observe the motions of the Earth, Moon and Sun in three dimensions to explain Sunrise and Sunset, and to see how we define a day, a month, and a year. Compare times of Sunrise and Sunset for different dates and locations. Relate shadows to the position of the Sun in the sky, and relate shadows to compass directions. 5 Minute Preview

Summer and Winter

Observe the tilt of Earth's axis and the angle that sunlight strikes Earth on June 21 and December 21. Compare day lengths, temperatures, and the angle of the Sun's rays for any latitude. The tilt of the Earth's axis can be varied to see how this would affect seasons. 5 Minute Preview

Causes of Seasons: Training for Gold

In this multi-part investigation, students follow Arban, an Olympic-hopeful snowboarder in Mongolia, as he searches for the perfect year-round training plan. Students will explore climates in different parts of the world, learning that seasons in the Southern Hemisphere are the opposite of seasons in the Northern Hemisphere. Students will then gather data on day length, height of the Sun, and solar intensity to see how variations in these factors relate to seasonal temperature changes. Finally, students will compare two proposed models of seasonal changes, a distance model and a tilted axis model, and use their data to determine what causes seasons on Earth. Preview

Causes of Seasons: Summer Down Under

Noor is an exchange student who will spend the year in Sydney, Australia. When she gets there in June, she is surprised about how chilly the weather is! June is the start of winter in Australia, and Noor and her brother Ahmed are determined to learn why. In this standalone lesson, students will gather data on day length, solar intensity, and temperature in New York and Sydney, then compare two proposed models to determine why seasons in Australia are the opposite of seasons in New York. Preview

Causes of Seasons: Mystery of the Midnight Sun

Ava is a university student from Miami who is studying climate and seasons in the Arctic. She is struck by how extreme seasons are in the Arctic compared to the much milder seasonal changes at home. In this standalone lesson, students will gather and compare data on day length and solar intensity in the two locations to explain why the Arctic experiences much larger seasonal changes than areas closer to the equator. Students will use a model of Earth's tilted axis to explain why some regions experience 24 hours of daylight in the summer and zero hours of daylight in the winter. Preview

Solar System Explorer

Survey the solar system, observing the length of a year and the orbital path of each object. The positions of the eight official planets are displayed, as well as one dwarf planet, Pluto. Learn about Kepler's Laws and how planets are classified. 5 Minute Preview

Solar System

Explore our solar system and learn the characteristics of each planet. Compare the sizes of planets and their distances from the Sun. Observe the speeds of planetary orbits and measure how long each planet takes to go around the Sun. 5 Minute Preview

Gravity Pitch

Imagine a gigantic pitcher standing on Earth, ready to hurl a huge baseball. What will happen as the ball is thrown harder and harder? Find out with the Gravity Pitch Gizmo. Observe the path of the ball when it is thrown at different velocities. Throw the ball on different planets to see how each planet's gravity affects the ball. 5 Minute Preview

Rock Cycle

Play the role of a piece of rock moving through the rock cycle. Select a starting location and follow many possible paths throughout the cycle. Learn how rocks are formed, weathered, eroded, and reformed as they move from Earth's surface to locations deep within the crust. 5 Minute Preview

Plate Tectonics

Move the Earth's crust at various locations to observe the effects of the motion of the tectonic plates, including volcanic eruptions. Information about each of the major types of plate boundaries is shown, along with their locations on Earth. 5 Minute Preview

Convection Cells

Explore the causes of convection by heating liquid and observing the resulting motion. The location and intensity of the heat source (or sources) can be varied, as well as the viscosity of the liquid. Use a probe to measure temperature and density in different areas and observe the motion of molecules in the liquid. Then, explore real-world examples of convection cells in Earth's mantle, oceans, and atmosphere. 5 Minute Preview

Hurricane Motion

Use data from up to three weather stations to predict the motion of a hurricane. The wind speed, wind direction, cloud cover and air pressure are provided for each station using standard weather symbols. 5 Minute Preview

Weather Maps

Learn about standard symbols used in meteorology to construct weather maps. Rain, sleet, snow, temperature, cloud cover, wind speed and direction, and atmospheric pressure can all be recorded at two different weather stations on a map. Describe weather patterns characteristic of high-pressure systems, low-pressure systems, warm fronts, and cold fronts. 5 Minute Preview

Coastal Winds and Clouds

Observe daily weather conditions in a coastal region. Measure temperatures and wind speeds at any location and use this data to map convection currents that form during the day and night. Explain the origin of land breezes and sea breezes. 5 Minute Preview

Weather Maps - Metric

Learn about standard symbols used in meteorology to construct weather maps. Rain, sleet, snow, temperature, cloud cover, wind speed and direction, and atmospheric pressure can all be recorded at two different weather stations on a map. Describe weather patterns characteristic of high-pressure systems, low-pressure systems, warm fronts, and cold fronts. 5 Minute Preview

Hurricane Motion - Metric

Use data from up to three weather stations to predict the motion of a hurricane. The wind speed, wind direction, cloud cover and air pressure are provided for each station using standard weather symbols. 5 Minute Preview

Coastal Winds and Clouds - Metric

Observe daily weather conditions in a coastal region. Measure temperatures and wind speeds at any location and use this data to map convection currents that form during the day and night. Explain the origin of land breezes and sea breezes. 5 Minute Preview

Coriolis Effect

The Coriolis effect causes winds to be deflected as they move across Earth's surface, resulting in circular patterns of winds. This effect is caused by two factors, Earth's rotation and frame of reference. In the Coriolis Effect Gizmo, students will build their understanding of this phenomenon using the analogy of two kids playing catch: first on a train, then on a merry-go-round, and finally on Earth's surface. 5 Minute Preview

Convection Cells

Explore the causes of convection by heating liquid and observing the resulting motion. The location and intensity of the heat source (or sources) can be varied, as well as the viscosity of the liquid. Use a probe to measure temperature and density in different areas and observe the motion of molecules in the liquid. Then, explore real-world examples of convection cells in Earth's mantle, oceans, and atmosphere. 5 Minute Preview

Coastal Winds: Kite Party

Sam is planning a kite flying party on Miami Beach, and she wants to know the best time of day to hold the party. To help Sam, students collect weather data for a day, explore how temperature changes are related to the formation of land and sea breezes, and explain how temperature and density cause convection currents to form. Preview

Coastal Winds: Sailing Away

One summer, Michael goes to stay with his uncle, a fisherman who works from a sailboat. Every morning, the wind blows the boat out to sea, and every afternoon the wind blows the sailboat back to shore. What is causing this pattern of winds? Preview

Coastal Winds: Balloon Festival

At a hot air balloon festival, Jasmine is wondering why the balloons rise up in the air. To investigate, she experiments by heating water in a beaker, observing how the water moves, and measuring the temperature and density in different parts of the beaker. By applying the principles of convection to the situation, Jasmine determines why hot air balloons rise. Preview

Carbon Cycle

Follow the path of a carbon atom through the atmosphere, biosphere, hydrosphere, and geosphere. Manipulate a simplified model to see how human activities and other factors affect the amount of atmospheric carbon today and in the future. 5 Minute Preview

Greenhouse Effect

Within this simulated region of land, daytime's rising temperature and the falling temperature at night can be measured, along with heat flow in and out of the system. The level of greenhouse gases present in the atmosphere at any given time can be adjusted, allowing the long-term effects to be investigated. 5 Minute Preview

Greenhouse Effect - Metric

Within this simulated region of land, daytime's rising temperature and the falling temperature at night can be measured, along with heat flow in and out of the system. The amount of greenhouse gases present in the atmosphere can be adjusted through time, and the long-term effects can be investigated. 5 Minute Preview

Carbon Cycle

Follow the path of a carbon atom through the atmosphere, biosphere, hydrosphere, and geosphere. Manipulate a simplified model to see how human activities and other factors affect the amount of atmospheric carbon today and in the future. 5 Minute Preview

Fighting Floods: The Water Cycle and Climate Change - Middle School

Paanee, a city in northeastern India, is flooding more than normal. Taking on the role of a hydrologist, the student analyzes data and designs a solution for Paanee to mitigate the effects of water cycle changes caused by global warming. Video Preview

Temperature and Sex Determination

Observe the sex ratios of birds and geckos as they hatch in an incubator. Vary the temperature of the incubator and measure the percentages of male and female hatchlings to determine if temperature has an effect on sex. 5 Minute Preview

Seed Germination

Perform experiments with several seed types to see what conditions yield the highest germination (sprouting) rate. Three different types of seeds can be studied, and the temperature, water and light in the germination chamber can be controlled. No two trials will have the same result so repeated trials are recommended. 5 Minute Preview

Growing Plants

Investigate the growth of three common garden plants: tomatoes, beans, and turnips. You can change the amount of light each plant gets, the amount of water added each day, and the type of soil the seed is planted in. Observe the effect of each variable on plant height, plant mass, leaf color and leaf size. Determine what conditions produce the tallest and healthiest plants. Height and mass data are displayed on tables and graphs. 5 Minute Preview

Temperature and Sex Determination - Metric

Observe the sex ratios of birds and geckos as they hatch in an incubator. Vary the temperature of the incubator and measure the percentages of male and female hatchlings to determine if temperature has an effect on sex. 5 Minute Preview

Inheritance

Create aliens with different traits and breed them to produce offspring. Determine which traits are passed down from parents to offspring and which traits are acquired. Offspring can be stored for future experiments or released. 5 Minute Preview

Measuring Trees

Measure the height, diameter, and circumference of trees in a forest. Count growth rings to determine the age of each tree. Grow the trees for several years and investigate how growth is affected by precipitation. 5 Minute Preview

Fast Plants^® 1 - Growth and Genetics

Grow Wisconsin Fast Plants^® in a simulated lab environment. Explore the life cycles of these plants and how their growth is influenced by light, water, and crowding. Practice pollinating the plants using bee sticks, then observe the traits of the offspring plants. Use Punnett squares to model the inheritance of genes for stem color and leaf color for these plants. 5 Minute Preview

Heredity and Traits - Middle School

As a bee scientist, students help a honey farm that has low honey production due to wasps. Students learn about bees, heredity and traits to determine which traits will help the bees defend their hives against the wasps. They then pick a new queen bee to pass on these traits to the bee colony. Video Preview

Cell Energy Cycle

Explore the processes of photosynthesis and respiration that occur within plant and animal cells. The cyclical nature of the two processes can be constructed visually, and the simplified photosynthesis and respiration formulae can be balanced. 5 Minute Preview

Dehydration Synthesis

Build a glucose molecule, atom-by-atom, to learn about chemical bonds and the structure of glucose. Explore the processes of dehydration synthesis and hydrolysis in carbohydrate molecules. 5 Minute Preview

Digestive System

Digestion is a complex process, involving a wide variety of organs and chemicals that work together to break down food, absorb nutrients, and eliminate wastes. But have you ever wondered what would happen if some of those organs were eliminated, or if the sequence was changed? Can the digestive system be improved? Find out by designing your own digestive system with the Digestive System Gizmo. 5 Minute Preview

Photosynthesis and Respiration: Mission to Mars

Excited for his summer internship at NASA, Jorge dives into his assignment of finding a way to provide oxygen for astronauts on a mission to Mars. Using the Plants and Snails and Cell Energy Cycle Gizmos, students will investigate photosynthesis, cellular respiration, and how these two processes are related to find a solution to Jorge's challenge. Preview

Photosynthesis and Respiration: Chloe's Goldfish

Chloe's goldfish are sick, and she needs to help them quickly! In this standalone lesson, students use the Plants and Snails and Cell Energy Cycle Gizmos to investigate cellular respiration and determine how to help Chloe's fish. Preview

Photosynthesis and Respiration: Henry's Snails

Henry is having trouble with his pet snails. To help, students will investigate the interdependence of photosynthesis and respiration using the Plants and Snails and Cell Energy Cycle Gizmos. Students will be challenged to use plants to create a stable environment for Henry's snails. Preview

Human Karyotyping

Sort and pair the images of human chromosomes obtained in a scan. Find differences in the scans of the various patients to find out specific things that can cause disease, as well as determining the sex of the person. 5 Minute Preview

Evolution: Mutation and Selection

Observe evolution in a fictional population of bugs. Set the background to any color, and see natural selection taking place. Inheritance of color occurs according to Mendel's laws and probability. Mutations occur at random, and probability of capture by predators is determined by the insect's camouflage. 5 Minute Preview

Genetic Engineering

Use genetic engineering techniques to create corn plants resistant to insect pests or tolerant of herbicides. Identify useful genes from bacteria, insert the desired gene into a corn plant, and then compare the modified plant to a control plant in a lab setting. 5 Minute Preview

Mouse Genetics (One Trait)

Breed "pure" mice with known genotypes that exhibit specific fur colors, and learn how traits are passed on via dominant and recessive genes. Mice can be stored in cages for future breeding, and the statistics of fur color are reported every time a pair of mice breed. Punnett squares can be used to predict results. 5 Minute Preview

Chicken Genetics

Breed "pure" chickens with known genotypes that exhibit specific feather colors, and learn how traits are passed on via codominant genes. Chickens can be stored in cages for future breeding, and the statistics of feather color are reported every time the chickens breed. Punnett squares can be used to predict results. 5 Minute Preview

Inheritance

Create aliens with different traits and breed them to produce offspring. Determine which traits are passed down from parents to offspring and which traits are acquired. Offspring can be stored for future experiments or released. 5 Minute Preview

Fast Plants^® 1 - Growth and Genetics

Grow Wisconsin Fast Plants^® in a simulated lab environment. Explore the life cycles of these plants and how their growth is influenced by light, water, and crowding. Practice pollinating the plants using bee sticks, then observe the traits of the offspring plants. Use Punnett squares to model the inheritance of genes for stem color and leaf color for these plants. 5 Minute Preview

Fast Plants^® 2 - Mystery Parent

In this follow-up to Fast Plants^® 1 - Growth and Genetics, continue to explore inheritance of traits in Wisconsin Fast Plants. Infer the genotype of a "mystery P2 parent" of a set of Fast Plants based on the traits of the P1, F1, and F2 plants. Then create designer Fast Plants by selectively breeding plants with desired traits. 5 Minute Preview

Genetics: Red-Hair Mystery

In this lesson series, students will investigate Mendel's Laws through the phenomenon of a red-haired girl born from two brown-haired parents. Students will use the Mouse Genetics Gizmo to make observations, gather data, and test their predictions. Students will create their own models of inheritance, learn about dominant and recessive alleles, and use Punnett Squares to make specific predictions of genetic outcomes. Preview

Genetics: White Kittens

In this standalone lesson, students investigate the phenomenon of a tabby cat with a litter of white kittens. Students will use the Mouse Genetics Gizmo to come up with and test their own models before learning about dominant and recessive alleles and applying their learning to solve the phenomenon. Preview

Genetics: Fancy Guinea Pigs

In this standalone lesson, students investigate the phenomenon of long-haired guinea pigs. After reviewing genetics basics, students will use Punnett Squares to model different genotype combinations, use the Mouse Genetics Gizmo to test their predictions, and then apply their learning to guinea pigs. Preview

Mouse Genetics (Two Traits)

Breed "pure" mice with known genotypes that exhibit specific fur and eye colors, and learn how traits are passed on via dominant and recessive genes. Mice can be stored in cages for future breeding, and the statistics of fur and eye color are reported every time a pair of mice breed. Punnett squares can be used to predict results. 5 Minute Preview

Mouse Genetics (One Trait)

Breed "pure" mice with known genotypes that exhibit specific fur colors, and learn how traits are passed on via dominant and recessive genes. Mice can be stored in cages for future breeding, and the statistics of fur color are reported every time a pair of mice breed. Punnett squares can be used to predict results. 5 Minute Preview

Fast Plants^® 1 - Growth and Genetics

Grow Wisconsin Fast Plants^® in a simulated lab environment. Explore the life cycles of these plants and how their growth is influenced by light, water, and crowding. Practice pollinating the plants using bee sticks, then observe the traits of the offspring plants. Use Punnett squares to model the inheritance of genes for stem color and leaf color for these plants. 5 Minute Preview

Fast Plants^® 2 - Mystery Parent

In this follow-up to Fast Plants^® 1 - Growth and Genetics, continue to explore inheritance of traits in Wisconsin Fast Plants. Infer the genotype of a "mystery P2 parent" of a set of Fast Plants based on the traits of the P1, F1, and F2 plants. Then create designer Fast Plants by selectively breeding plants with desired traits. 5 Minute Preview

Genetics: Red-Hair Mystery

In this lesson series, students will investigate Mendel's Laws through the phenomenon of a red-haired girl born from two brown-haired parents. Students will use the Mouse Genetics Gizmo to make observations, gather data, and test their predictions. Students will create their own models of inheritance, learn about dominant and recessive alleles, and use Punnett Squares to make specific predictions of genetic outcomes. Preview

Genetics: White Kittens

In this standalone lesson, students investigate the phenomenon of a tabby cat with a litter of white kittens. Students will use the Mouse Genetics Gizmo to come up with and test their own models before learning about dominant and recessive alleles and applying their learning to solve the phenomenon. Preview

Genetics: Fancy Guinea Pigs

In this standalone lesson, students investigate the phenomenon of long-haired guinea pigs. After reviewing genetics basics, students will use Punnett Squares to model different genotype combinations, use the Mouse Genetics Gizmo to test their predictions, and then apply their learning to guinea pigs. Preview

Rainfall and Bird Beaks

Study the thickness of birds' beaks over a five-year period as you control the yearly rainfall on an isolated island. As the environmental conditions change, the species must adapt (a real-world consequence) to avoid extinction. 5 Minute Preview

Natural Selection

You are a bird hunting moths (both dark and light) that live on trees. As you capture the moths most easily visible against the tree surface, the moth populations change, illustrating the effects of natural selection. 5 Minute Preview

Microevolution

Observe the effect of predators on a population of parrots with three possible genotypes. The initial percentages and fitness levels of each genotype can be set. Determine how initial fitness levels affect genotype and allele frequencies through several generations. Compare scenarios in which a dominant allele is deleterious, a recessive allele is deleterious, and the heterozygous individual is fittest. 5 Minute Preview

Evolution: Mutation and Selection

Observe evolution in a fictional population of bugs. Set the background to any color, and see natural selection taking place. Inheritance of color occurs according to Mendel's laws and probability. Mutations occur at random, and probability of capture by predators is determined by the insect's camouflage. 5 Minute Preview

Rainfall and Bird Beaks - Metric

Study the thickness of birds' beaks over a five year period as you control the yearly rainfall on an isolated island. As the environmental conditions change, the species must adapt (a real-world consequence) to avoid extinction. 5 Minute Preview

Pimple Poppers: Natural Selection and Antibiotic Resistance - Middle School

Students investigate why a strain of Staphylococcus aureus does not respond to an antibiotic. Using experimental data and natural selection principles, they find that this S. aureus has adapted to become antibiotic-resistant. Students design a new experiment to test other antibiotics to stop growth and cure the patient’s infection. Video Preview

Evolution: Natural and Artificial Selection

Observe evolution in a fictional population of bugs. Set the background to any color, and see natural selection taking place. Compare the processes of natural and artificial selection. Manipulate the mutation rate, and determine how mutation rate affects adaptation and evolution. 5 Minute Preview

Genetic Engineering

Use genetic engineering techniques to create corn plants resistant to insect pests or tolerant of herbicides. Identify useful genes from bacteria, insert the desired gene into a corn plant, and then compare the modified plant to a control plant in a lab setting. 5 Minute Preview

Molecule Builder

Create molecules using building blocks of carbon, hydrogen, oxygen, nitrogen, and other elements. Connect atoms by bonds, then create double or triple bonds if desired. For each completed molecule, write the chemical formula and, if the molecule is included in the database, observe the 3D structure. Create a variety of challenge molecules including cyclic molecules and isomers. 5 Minute Preview

Chemical and Physical Changes - Middle School

The Secret Service recently arrested suspects accused of counterfeiting coins from 1915 valued at $50,000 each. The students act as a forensic scientist to investigate the crime scene and the evidence. Students learn about chemical and physical changes to recreate the methods used to make the coins as evidence for the trial. Video Preview

Chemical Changes

Chemical changes result in the formation of new substances. But how can you tell if a chemical change has occurred? Explore this question by observing and measuring a variety of chemical reactions. Along the way you will learn about chemical equations, acids and bases, exothermic and endothermic reactions, and conservation of matter. 5 Minute Preview

Chemical and Physical Changes - Middle School

The Secret Service recently arrested suspects accused of counterfeiting coins from 1915 valued at $50,000 each. The students act as a forensic scientist to investigate the crime scene and the evidence. Students learn about chemical and physical changes to recreate the methods used to make the coins as evidence for the trial. Video Preview

Temperature and Particle Motion

Observe the movement of particles of an ideal gas at a variety of temperatures. A histogram showing the Maxwell-Boltzmann velocity distribution is shown, and the most probable velocity, mean velocity, and root mean square velocity can be calculated. Molecules of different gases can be compared. 5 Minute Preview

Phase Changes

Explore the relationship between molecular motion, temperature, and phase changes. Compare the molecular structure of solids, liquids, and gases. Graph temperature changes as ice is melted and water is boiled. Find the effect of altitude on phase changes. The starting temperature, ice volume, altitude, and rate of heating or cooling can be adjusted. 5 Minute Preview

Phases of Water

Heat or cool a container of water and observe the phase changes that take place. Use a magnifying glass to observe water molecules as a solid, liquid, or gas. Compare the volumes of the three phases of water. 5 Minute Preview

Melting Points

Every substance has unique transition points, or temperatures at which one phase (solid, liquid, or gas) transitions to another. Use a realistic melting point apparatus to measure the melting points, boiling points, and/or sublimation points of different substances and observe what these phase changes look like at the microscopic level. Based on the transition points, make inferences about the relative strengths of the forces holding these substances together. 5 Minute Preview

Protecting Permafrost: Heat Transfer Highway - Middle School

Thawing permafrost threatens the stability of critical infrastructure in the Arctic community of Mountain Harbor, Alaska. Students take on the role of a civil engineer to design heat transfer solutions to protect permafrost in a warming climate. Video Preview

Phase Changes: Mountain Spaghetti

In this lesson series, students will help Kayla, a cooking enthusiast who is having trouble making good spaghetti in her new home in the mountains. Students will investigate phase changes, the effect of altitude and air pressure on boiling point, and the molecular causes of phase changes. Preview

Phase Changes: Boil in a Bag

Dad forgets to bring the cooking pot on a camping trip, throwing the macaroni and cheese dinner into doubt. Luckily, he comes up with an ingenious solution involving a plastic bag. Students will investigate how temperature relates to phase changes to explain why this works. Preview

Phase Changes: Dance of the Molecules

After a snowstorm cuts power and water, Ethan needs to melt ice and boil the resulting water to cook dinner. This phenomenon leads him to thinking about why water changes from one phase to another. In this standalone lesson, students will investigate what is happening at the molecular level to cause phase changes. Preview

Phase Changes: Fast Eggs

Kayla loves to cook deviled eggs, but she hates to wait for the eggs to hard boil. After receiving a pressure cooker as a birthday gift, she is thrilled to discover she doesn't have to wait as long. In this standalone lesson, students gather and analyze data to investigate the relationship between air pressure, altitude, and boiling point. Preview

Balancing Chemical Equations

Balance and classify five types of chemical reactions: synthesis, decomposition, single replacement, double replacement, and combustion. While balancing the reactions, the number of atoms on each side is presented as visual, histogram, and numerical data. 5 Minute Preview

Chemical Equations

Practice balancing chemical equations by changing the coefficients of reactants and products. As the equation is manipulated, the amount of each element is shown as individual atoms, histograms, or numerically. Molar masses of reactants and products can also be calculated and balanced to demonstrate conservation of mass. 5 Minute Preview

Chemical Changes

Chemical changes result in the formation of new substances. But how can you tell if a chemical change has occurred? Explore this question by observing and measuring a variety of chemical reactions. Along the way you will learn about chemical equations, acids and bases, exothermic and endothermic reactions, and conservation of matter. 5 Minute Preview

Chemical and Physical Changes - Middle School

The Secret Service recently arrested suspects accused of counterfeiting coins from 1915 valued at $50,000 each. The students act as a forensic scientist to investigate the crime scene and the evidence. Students learn about chemical and physical changes to recreate the methods used to make the coins as evidence for the trial. Video Preview

Smelling in the Rain: Designing Solutions to Improve Air Quality - Middle School

A respiratory physiologist is concerned about the number of asthma attacks in children within her community. On certain days, the number is higher than the respiratory physiologist might expect. She thinks something in the environment is causing more rescue inhaler use on those days. As an air quality engineer, students will work collaboratively with a respiratory physiologist to learn how some air pollutants are released directly from sources while others are formed through chemical reactions. Students will develop a system model to test design solutions to recommend a plan to help decrease air pollution in a community with a record number of asthma cases in children. Video Preview

Crumple Zones

Design a car to protect a test dummy in a collision. Adjust the length and stiffness of the crumple zone and the rigidity of the safety cell to determine how the car will deform during the crash. Add seat belts and/or airbags to prevent the dummy from hitting the steering wheel. Three different body types (sedan, SUV, and subcompact) are available and a wide range of crash speeds can be used. 5 Minute Preview

Save a Satellite - Middle School

Students acting as spacecraft navigation engineers apply their knowledge of Newton’s Third Law of Motion to launch a communication satellite into a stable orbit around Earth. When students learn of an impending collision with space debris, they must use their knowledge of gravitational forces and Newton’s Laws to correctly maneuver their satellite to a new, stable orbit. Video Preview

Free-Fall Laboratory

Investigate the motion of an object as it falls to the ground. A variety of objects can be compared, and their motion can be observed in a vacuum, in normal air, and in denser air. The position, velocity, and acceleration are measured over time, and the forces on the object can be displayed. Using the manual settings, the mass, radius, height, and initial velocity of the object can be adjusted, as can the air density and wind. 5 Minute Preview

Fan Cart Physics

Gain an understanding of Newton's Laws by experimenting with a cart (on which up to three fans are placed) on a linear track. The cart has a mass, as does each fan. The fans exert a constant force when switched on, and the direction of the fans can be altered as the position, velocity, and acceleration of the cart are measured. 5 Minute Preview

Force and Fan Carts

Explore the laws of motion using a simple fan cart. Use the buttons to select the speed of the fan and the surface, and press Play to begin. You can drag up to three objects onto the fan cart. The speed of the cart is displayed with a speedometer and recorded in a table and a graph. 5 Minute Preview

Tackling Concussions: Testing Helmet Design Using Laws of Motion - Middle School

Concussion rates in youth impact sports are high despite the use of helmets. In this STEM case, students act as materials scientists to learn about the physics behind concussions and helmet function. Students will use their understanding of Newton’s First and Second Laws of Motion to investigate helmet padding material to determine which material is best at reducing force during an impact. Video Preview

Save a Satellite - Middle School

Students acting as spacecraft navigation engineers apply their knowledge of Newton’s Third Law of Motion to launch a communication satellite into a stable orbit around Earth. When students learn of an impending collision with space debris, they must use their knowledge of gravitational forces and Newton’s Laws to correctly maneuver their satellite to a new, stable orbit. Video Preview

Newton’s Laws: Race to the Finish

In this three-part series, students become motion analysts using the Force and Fan Carts Gizmo to figure out which racer will win. They investigate how changes in force, mass, and friction affect the motion of carts, collecting and interpreting data to build and revise models. Students use their findings to deepen their understanding of Newton’s First and Second Laws and apply evidence to justify their predictions in a final race challenge. Core topics include the effects of force and mass on acceleration, the role of friction, and balanced and unbalanced forces. Preview

Newton’s 1st Law: Robotics Showdown

In this standalone investigation, students act as robotics competitors trying to program a cart to stop at a target. Using the Force and Fan Carts Gizmo, they investigate how balanced and unbalanced forces affect the motion of a cart and see Newton’s First Law in action. By testing different surface types and fan forces, students learn how friction and applied force interact, discovering why objects stay at rest or in motion unless acted on by another force. The investigation focuses on motion, inertia, balanced and unbalanced forces, and friction. Preview

Newton’s 2nd Law: Speed Lab Challenge

In this standalone investigation, students take on the role of motion analysts using the Force and Fan Carts Gizmo to figure out which racer will win. Using the Force and Fan Carts Gizmo, they collect and analyze data to identify patterns between force, mass, and speed. Students apply Newton’s Second Law to explain why some carts accelerate faster than others, then use scientific evidence to justify which racer will win. Topics include the relationship between force, mass, and acceleration, and interpreting data to support scientific explanations. Preview