Try This At Home: Toys in the International Space Station and Space Shuttle Endeavor

Toys in Microgravity from NASA

The podcast episode was about what happens to human bodies in microgravity and that would be hard to replicate at home. However, astronauts on board the International Space Station and on the Space Shuttle Endeavor have been experimenting with kids’ toys to help demonstrate how microgravity affects everyday objects. 

If possible, gather the toys and test them to see how they work in normal gravity. Otherwise, the videos from NASA show astronauts on Earth playing with the toys first. Then, pause the video and take some time thinking about how the action of the toys may be affected by microgravity. Consider how the action of the toy is impacted by things like gravity, friction, and the action of simple machines.

You can download the International Toys in Space Video Resource Guide and Toys in Space II Video Resource Guide.

Try This At Home: Multiple approaches to solving Quadratic Equations.

Quadratic Equations – Four ways to solve

This is a quadratic equation.

ax^2+bx+c=0

In our podcast we mentioned several ways of solving quadratic equations, including a “new” way based on the work of Po Shen Loh (who credits the work of Viète, the Babylonians and the Greeks). He posts updates to his method on his website if you want to read about it in his words.

When you graph a quadratic equation the curved shape you get is called a parabola. Typically when people “solve” a quadratic equation they are looking for the values that correspond to where the parabola crosses the x-axis.

In this activity, you can find four different methods for solving a quadratic equation. Some of them are easier to use than others and the last 3 methods will even allow you to solve quadratics that have complex (imaginary) numbers in their solution.

If you want to give all of the methods a try, download the file and have fun!

Try This At Home: Sourdough Bread Citizen Science

Sourdough Bread – Citizen Science

In our podcast episode we talked about the work done at the Rob Dunn lab at North Carolina State. He’s done TED talks about sourdough microbes and worked on the Global Sourdough Project which we talked about on the podcast. 

The Global Sourdough Project was a form of citizen science because it used members of the public to follow an experimental procedure to collect the data that his lab then analyzed.

Now his lab is working on a new project where they need people to make and characterize their sourdough starters and provide them with data that they can analyze to learn more about the microbes in sourdough. This is a great opportunity to contribute to science from your own kitchen and make a sourdough starter you can use to make lots of delicious things. So, it is a win-win.

Head on over to Wild Sourdough to get started!       

Try This At Home: Scientific Method with Pendulums

Scientific Method – Pendulums

Now that you’ve listened to our podcast, you probably have a different view of how the parts of the scientific method fit together. Circle the picture below the best represents the order and direction steps of the scientific method fit together.

To practice thinking about how this plays out in real life we are going to consider pendulums. If you wanted to discover properties of pendulums depending on the weight and length of the string, what are ways you could start at three different  parts of the scientific method. Write them down

Did you start by asking a question? By designing an experiment? By doing background research? By coming up with a hypothesis? By observing some pendulums and collecting preliminary data? 

All of these are reasonable places to start. Try it.

Make a flow chart for each of these starting points for  the scientific method.  

  1. Start with the following question and plan a way through the scientific method: How does the length of the string and the weight affect the number of swings of a pendulum?
  2. Start with some observations about pendulums and plan a way to test how the length of the string and the weight affect the number of swings.
  3. Start with background research and develop a hypothesis for how the length of the string and the weight affect the number of swings.

Did you notice similarities and differences in how you get started? Will you end up with the same conclusions? Is one starting point inherently better than the others? Why or why not?

Design your experiment.

Now that you have come at the problem from different directions it is time to design a good experiment. Your challenge is to come up with a hypothesis and a procedure to use to test your hypothesis using the following materials: string, ruler, tape, timer, washers or paperclips to use as weights.

Here are some questions that will help guide you in your design.

  1. What variables will you be recording for your experiment? Which ones are independent (manipulated) variable(s) and which are the dependent (responding) variable(s)?
  2. You are working with a couple of different variables, when developing your hypothesis do you want to have a separate hypothesis for each variable or combine them?
  3. How will you measure the number of swings?
  4. Will you test each variable more than once.
  5. How can you ensure that each test is the same? How will you drop the pendulum? How will you secure the pendulum? Do you think holding the pendulum string with your hand will work well?
  6. How will you share your conclusions with others?

Did you come up with any new questions to test?

Frequently, scientists will start by testing on thing and then get curious about another aspect of the thing they were studying. This helps them keep discovering more about the world. What new questions or observations occurred to you while doing your experiment?