A student is conducting an investigation to show how magnetic forces can act at a distance from

an object.

What can the student conclude from the data that he gathered in his investigation?

a. The force is not related to the distance from the object.

b. The force of the magnet becomes stronger the farther it is from the object.

c. The force is stronger with less distance between the magnet and the object.

d. The force of the magnet becomes stronger and then weaker the farther it is from the object.

A science teacher asks her class to compare the way in which heat is transferred to water in a

pond as opposed to soil at the edge of the pond. Which of the following investigations will help

them make this comparison?

a. Mix water and soil in a container, place it in the sun, and measure the temperature of the

container.

b. Place soil and water in separate containers, place them indoors, and monitor the temperature

of the containers.

c. Place soil and water in separate containers, place them in the sun, and monitor the

temperatures of each container.

d. Place soil in the bottom of a container and water on top, place it in the sun, and measure the

temperature of the container.

Jasmyne finalized a design of a circuit that made two lamps in her room light up at once. 

The image below shows her initial design, which originally did not work. What change did she make to

this initial design that eventually resulted in both lights working?

The students noted that the temperature of the ice water and the container stayed constant until

the ice was completely melted. Why was it important to monitor the temperature of both the ice

water and the container to explain this observation?

a. to show that there was no thermal energy transfer during this time

b. to show that thermal energy was transferred to the container and then to the ice, causing it

to melt

c. to show that thermal energy was transferring from the ice water to the container and the

surrounding air

d. to show that thermal energy was transferred to the container but not to the ice, which kept it

from warming up

A student rubs a comb on a cloth. She then holds the comb 30 centimeters above some small

pieces of paper on a table, but the paper does not move. When the comb is moved closer to the

paper, the paper moves through the air to the comb.

Which statement explains why the paper does not move toward the comb when the comb is

farther away?

a. The paper is not attracted to the comb.

b. The comb and the paper have identical charges.

c. Only metallic objects can be attracted to each other.

d. The attractive field from the comb is weaker farther from the comb.

Ella’s town has two pools — larger pool where older kids swim, and a small wading pool where

parents bring their smaller children to play. After a cold rainfall, the older kids jumped right back

in to the larger pool, but all of the parents brought their smaller children home because the water

in the smaller pool was too cold. How could Ella model this idea for her classmates?

a. Place a large container of warm water next to a small container of cold water.

b. Add a small amount of cold water to both a large and small container of warm water.

c. Add several ice cubes to a large container of water and one ice cube to a smaller container.

d. Place models of older kids in a large container of water and models of smaller children in a

smaller container of water.

In this performance task, you will answer 3 questions.

Students have been challenged to create and test a simple electromagnet. Students will first

create a design for the electromagnet. They will then test factors that affect the strength of the

magnetic field.

An electromagnet is made by coiling wire around a metal core. An electrical current passed

through the wire causes the metal core to become magnetized. The investigation uses a setup as

shown. Direct current from a battery can be passed through the wire. Students perform several

tests, including

• varying the number of turns of the wire around the metal core,

• changing the position of the magnet, and

• switching the wire to opposite battery terminals.

The students vary the number of turns of wire around the metal core, using a 9–V battery as the

source of current. They test the strength of the electromagnet for each trial.

Based on their temperature measurements and their understanding of the effect of mass on

thermal energy transfer, students have determined that they can increase the length of time it

takes their ice to melt by increasing the mass of the ice in the container.

Time (in

minutes )

Temperature of Ice Water (in °C)

Trial 1 Trial 2 Trial 3

5 0 0 0

10 0 0 0

15 0 2 0

20 0 4 0

25 2 6 0

30 4 8 0

35 6 10 2

40 8 12 4

45 10 14 6

50 12 16 8

Part A – Circle the trial that shows the results students obtained by increasing the mass of ice in

the container.

a. Trial 1

b. Trial 2

c. Trial 3

A teacher sprinkles some iron shavings on a clear tray. She places two magnets in the shavings

with the north ends facing each other.

Based on the cause-and-effect relationship between the magnets, which phenomenon is the

teacher modeling for her students?

a. electrical force

b. attractive force

c. field of repulsion

d. gravitational attraction

ose found four turtle eggs sitting in the grass in his backyard. He plans to take them to a nature

center near his house where a scientist will help them. Jose needs to design a closed container

to transport them to the nature center. Two important criteria are that the eggs must be kept

warm—at a temperature between 27–32 degrees Celsius (C), and the eggs must be protected so

the shells do not break.

Jose wants to put a packet around the eggs that meet both criteria. He sets up three different

possible combinations of water, calcium chloride, and baking soda in three different sandwich

bags. Each bag represents a possible design for a packet. All three bags sit for the same amount

of time.

The table below shows his observations.

Which design should Jose choose for his packet? Why?

a. Bag 1—energy was released in the form of a liquid, which will help protect the eggs.

b. Bag 2— energy was released in the form of gas, which will help protect the eggs.

c. Bag 3—energy was absorbed in the form of a solid, which will help protect the eggs.

d. None of the bags keep the eggs warm or provide protection.

Students used iron filings to map the lines of magnetic force between the bar magnet and

electromagnet. They drew diagrams to model the lines of magnetic force when the magnets

were close together and then far apart. The stronger the force, the denser the magnetic field

lines. Which of the following describes the diagrams when the magnets are in different positions?

Choose all that apply.

a. When the magnets are close together, the lines of force between the poles are also close

together.

b. The lines of force between the electromagnet and bar magnet are closest when the magnets

are far apart.

c. The lines of force between the two magnets when they are close are similar to when the

magnets are far apart.

d. When the electromagnet’s south pole and bar magnet’s north pole are close together, there

are few lines of force between the magnets.

e. The lines of force at the electromagnet’s north pole and bar magnet’s south pole change

little with the distance between the magnets.

In addition to increasing the mass of the ice in the container, students tried to disrupt the

thermal energy transfer between the air molecules and the ice water by using materials that

do not transfer thermal energy efficiently. These materials are known as thermal insulators.

Students found that aluminum foil was a poor insulator but Styrofoam was a good insulator.

Rank these insulating designs that students created from best to worst by placing the numbers 1

through 4 next to the images (where 1 = best and 4 = worst).

sides wrapped in Styrofoam

sides wrapped in aluminum foil

plain container

sides and top wrapped in Styrofoam