Dancing Candy Hearts

Around Valentine’s Day, my kids get lots of those candy conversation hearts.  I remember as a kid, I loved reading the messages on them.  The messages are a bit different these days (“Text me”?)  Save a few of those hearts to do this quick 5 minute science experiment.  Use up some candy, do a little science, watch a little dance.

Here’s what you’ll need to get started:

  • Candy Conversation Hearts
  • Tall clear glass (we used a tall glass and a test tube)
  • Baking Soda
  • Vinegar
  • Water
  • Measuring spoon

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Add 1 cup of water to a clear tall glass or tall test tube.  You can color yours purple or red for Valentine’s Day but that is totally optional.

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Add in 2 teaspoons of baking soda and mix well.

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Add a few candy hearts to the glass.

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We used one of each color.img_0620Watch the hearts sink to the bottom of the glass.
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Add about 1/4 cup of vinegar to the glass slowly (or else it will will overflow!)

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Watch the candy hearts dance… or in our case, only the pink and orange hearts danced.  The rest stayed happily at the bottom of the glass.img_0627

It really looked so cool watching the hearts float up and then sink down.

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We will definitely be trying this again by testing the different colored hearts separately, testing different brands and testing different fizzy liquids to see if any of those change how the hearts behave.

For more Valentine’s Science Activities, try these:

For more floating and sinking activities, try these:

The Science Behind the Activity:

This is a great experiment demonstrating sinking and floating.  The hearts are denser than the liquid so they initially sink when you put them in.  When the vinegar is added, the reaction creates carbon dioxide gas.  As the carbon dioxide gas bubbles attach to the surface of the hearts, they decrease the density of the hearts and the hearts float to the top.  At the surface of the liquid, the gas bubbles pop and the hearts sink back down.  The process keeps repeating until there isn’t enough carbon dioxide left to raise the hearts.

To see where I got the idea from and more details, follow the link below:

http://inspirationlaboratories.com/valentine-candy-science-dancing-hearts/

 

Hopping Corn and Cranberries

Just in time for Thanksgiving, I’ve got a fun quickie experiment to do with your cranberries and some popcorn kernels.  If you’ve tried my Dancing Raisins experiment, then this will be familiar.

Here’s what you’ll need to get started:

  • Dried Cranberries
  • Popcorn kernels
  • Soda water, Ginger Ale, Sprite, Club Soda, sparkling water or whatever clear bubbly (kid-friendly!) you have at home
  • clear jars or cups

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I asked the tots to touch the dried cranberries and the popcorn kernels and describe how each felt.

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For younger tots, I prompted them with simple questions such as:

  • Is it soft or hard?
  • Is it smooth or bumpy?
  • Is it sticky or slimy?

Fill one cup with water and one cup with soda (we used diet Ginger Ale because that’s what we have at home), but any clear bubbly soda should work fine.

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We also compared the difference between the soda and the water.  They immediately noted the difference in color and the presence of bubbles in the soda.

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Next, I asked them what they thought would happen if the cranberries were added to the water? They all thought they would sink to the bottom.  After making their predictions, they added the cranberries to test their theories.

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Yes, the cranberries sunk to the bottom.

I then asked them what they thought would happen if the cranberries were put in the soda.  They again thought that they would sink.

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So they did sink… at first.  But then they “hopped” to the surface… and then dropped again… and rose again.

We repeated the same steps with the popcorn kernels.  When we added the popcorn kernels to the water, they sank as well.

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Then we added them to the Ginger Ale.  And discovered that the popcorn kernels did the same thing!

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It was mesmerizing to watch them “hop” up and down.

We will definitely be trying this again with several other sodas and sparkling water!  You can also make a bubbly solution with vinegar and baking soda as well.

Another extension/variation of this experiment is to try out different items, other than cranberries that might behave in a similar way, such as raisins, dried macaroni, etc…  Search your pantry.  The options are endless.  Happy Hopping!

Also, try my Dancing Raisins experiment for a different twist to a similar activity!

The Science behind the Activity:

This is a great experiment demonstrating sinking and floating.  Cranberries are denser than the liquid so they initially sink when you put them in.  As the carbon dioxide gas bubbles attach to the surface of the cranberries, they decrease the density of the cranberry and the cranberry floats to the top (dances and shimmies its way to the top!) At the surface of the liquid, the gas bubbles pop and the cranberry sinks back down.  The process keeps repeating until there isn’t enough carbon dioxide left to raise the cranberries.  The same holds true for the popcorn kernels.

 

Orange Float or Sink?

Here’s a simple snack time experiment!  All you need is water, a glass and a Clementine (or Cuties, as my kiddos call them).  Takes only a few minutes.

Here’s what you need to get started:

  • small oranges like mandarins or clementines
  • Tall glass with water

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Ask your kids to predict what they think will happen when you place the orange in the water.

Add the orange to the water and observe.  Were their predictions correct?

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Peel the orange.  Now predict what will happen when you place the unpeeled orange into the water.

Add the unpeeled orange to the water and observe.  Were their predictions correct?  Ask them why the orange behaved differently with and without the peel.

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From these results, the boys wanted to know if it was just the peel that floated, so we tested that as well.

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The peels floated at the top as well.  What’s going on? We discussed the differences between the peel and the orange.  Is there air inside the orange?  What is special about the peel that it floats and also causes the entire orange to float?  Since the boys and I have done several floating and sinking experiments together, they immediately suggested that air and density had something to do with our observations.

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This was a great investigation on floating and sinking using oranges and a great snack time “quickie” science experiment!

The Science behind the Activity:

Oranges contain quite a bit of air inside them which causes the overall density of the orange to be less than that of water, so it floats.  Also, the peel keeps the water from getting inside the orange.  Once the peel is removed, water can enter through the membranes of the orange slices and will cause the orange to increase in density and sink.

For a more complicated explanation involving buoyancy and Archimedes’ Principle (a concept that is more challenging for most toddlers and preschoolers to understand) please visit the link where I got my idea from: http://www.playdoughtoplato.com/orange-buoyancy-science-experiment/ 

 

Sink the Pots of Gold!

I set this experiment up in about 3 minutes for my 3 superheroes and they are STILL laughing and playing as I write this blog post!  So easy, so fun and perfect for the warm late winter’s afternoon we have right now in Mid-March.  I’m using Pots of Gold since St. Patrick’s Day is tomorrow, but this can be done with any plastic cup or small container and rocks or pennies.

Here’s what you need to get started:

  • Bin for the water (I use plastic shoebox bins from the Dollar Store)
  • Food coloring (optional – I used green for this activity)
  • Candy Kettles (any party store has them seasonally) or any small plastic cup
  • Rocks (I painted mine gold for St. Patrick’s Day)
  • Pennies (we needed almost 100!)

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I set up the tray for them

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I had the boys place one gold nugget in the water and watch it sink.  Then they placed the kettle in the water and it floated.

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Next, I asked them to add the gold to the pot until it sank.

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My littlest one loved this.  He also practiced his counting!  (He can only go up to 5 so I used BIG rocks for him) Looks like the pot is almost about to sink!

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Oh no!  Too much gold!  The pot sank!

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The boys had so much fun playing with this!  My eldest son used pennies in his pot.  It took him over 50 pennies!

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I had a BIG mess on the floor.  So, I recommend doing this outside 🙂

This activity is a St. Patrick’s version of my original floating activity: What Floats Your Boat?

The Science behind the Activity:

When doing this experiment with older kids, I discuss the concept of buoyancy, which is the ability of an object to float when placed in a fluid.  Surface area greatly affects the buoyancy of an object.  The larger surface area allows the force (weight of the gold/pennies) to be spread out over a larger area, thus allowing the pot to float even with the “treasures”. The larger surface area displaces more water.  This is why a large hull in a ship is able to float on water.  And if the ship is floating on salt water (like the ocean) it can carry even more cargo since salt water is denser than pure water.  It’s a bit more complicated than my simplified explanation, but hopefully you get the point.  And for the little ones, it’s just fun to sink the pots and get wet:)

For more details and to see where I got my idea from, please visit: http://littlebinsforlittlehands.com/st-patricks-day-sink-float-science-experiment-with-pennies/

For more St. Patrick’s Day Science, check out the following activities:

 

Apple Float or Sink?

Fall is a fun time to play with apples and go apple picking.   If you have a few extra apples laying around, here’s a great investigation for the tiny tots in your home to investigate whether apples sink or float when placed in water.

Here’s what you need to get started:

  • apples of different varieties (we used, Fuji, Granny Smith and Red Delicious)
  • Bin with water
  • Knife (to cut apples, for adult use only)

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Have your superheroes hold the apples in their hands and predict what will happen when it is placed in water.  We tried 3 different types of apples, making a hypothesis (prediction) before placing each one in the water.

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First the Granny Smith apple

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Then the Red Delicious and Fuji apples

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All three apples floated.  There was no difference between the 3 varieties.  But why did they float?  Apples have a lot of small air pockets inside that cause them to float in water.

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But what about the individual apple parts?  Do all the apple parts float? We decided to find out by cutting an apple open and testing each part in a cup of water.

What we noticed was the apple pieces and the peel still floated in water.

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But, the stem and the seeds did not float.

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This was a great investigation on floating and sinking using apples!  And while you have a bunch of apple parts lying around, try exploring your 5 senses using apples.  Or let the little ones “bob” for apples!

For more Apple Science Activities, try:

The Science behind the Activity:

Apples contain quite a bit of air inside them which causes the overall density of the apple to be less than that of water, so it floats.  By testing the individual parts, we can see that not all parts of the apple float in water but when all the parts are put together they do.

 

What Floats Your Boat?

What kid doesn’t like to play with water?  Add a bit of science and math to your water play next time with this easy experiment to set up at home.  I used to to this same experiment with my middle schoolers in the classroom to demonstrate concepts in buoyancy but for the little ones, it is just fun!

Here’s what you need to get started:

  • small bin or deep dish for water or even your water table!
  • water (I added some blue color for fun)
  • Foil
  • pennies or small rocks

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Add some water to the bin.  My kids love colored water so we added a drop to simulate ocean water.

The tricky part is making the foil boat.  Younger kids might have trouble with this and might tear their boats.  Feel free to help them. Ours looked like bowls.

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Place the foil boat in the water and make sure it floats and doesn’t have any leaks.

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Next, we added pennies, one by one, to the boat.

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You will be amazed at how many pennies this little foil boat can hold!

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And then there was one penny to many… and the boat finally sank!

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Lastly, they colored in their lab sheet and had to write the number of pennies their boat held before sinking.  There you go!  Math, science, coloring and some healthy sibling competition:)

Extensions for older kids: Compare what happens to 2 identical pieces of foil when placed in water: one in the shape of a boat and one wadded up super tight to minimize the amount of air trapped inside.  Why do you think this is possible?  Also, try this experiment with salt water.  Predict what effect salt water would have on the boat’s ability to carry cargo.

The Science behind the Activity:

When doing this experiment with older kids, I discuss the concept of buoyancy, which is the ability of an object to float when placed in a fluid.  Surface area greatly affects the buoyancy of an object.  The larger surface area allows the force (weight of the cargo/pennies) to be spread out over a larger area, thus allowing the boat to float even with the “cargo”. The larger surface area displaces more water.  This is why a large hull in a ship is able to float on water.  And if the ship is floating on salt water (like the ocean) it can carry even more cargo since salt water is denser than pure water.  It’s a bit more complicated than my simplified explanation, but hopefully you get the point.  And for the little ones, it’s just fun to sink the boats:)

For a more detailed explanation click on this link:

http://www.coolscience.org/CoolScience/Teachers/Activities/FoilBoats.htm

Homemade Lava Lamps

I loved those fancy lava lamps when I was a kid, but alas, my parents did not buy one for me.  Here’s a DIY Homemade Lava Lamp with some science sneaked in!  Super easy and mesmerizing for the superheroes in your life!

Here’s what you need to get started:

  • Empty water bottle (or any clear bottle)
  • vegetable oil (any light colored oil will do but this is probably the cheapest)
  • Food coloring
  • alka seltzer tablets

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Fill the bottle a little more than halfway with oil.

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Then add water to it until it’s about an inch or two from the top of the bottle.

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Add about 5-10 drops of food coloring. Watch how the color drips down through the oil to the water.

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Break one of the alka seltzer tablets into 4-5 pieces.  Use caution with young children who might be tempted to put this in their mouths!  It is a cold medication and should not be ingested by children!  IMG_1984

Add one piece to the bottle and watch the magic begin!

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Once the alka seltzer tablet has completely dissolved, add another one and watch the colored bubbles rise and sink again!  Repeat as many times as you’d like!  You can even try adding some glitter for some extra fun!

The Science behind the Activity:

Water and oil are insoluble, they do not mix.  Water is denser than oil and stays as a separate layer at the bottom of the bottle.  Food coloring is soluble in water so it colors the water but not the oil.  When the alka seltzer is added, it forms gas bubbles that rise to the top, “dragging” the colored water along with it.  As the water reaches the top and the gas bubbles pop near the surface of the oil, the denser water falls back down through the oil.  The process keeps repeating itself until the alka seltzer has completely dissolved an no longer forms any bubbles.

This activity can be done with adding salt instead of alka seltzer (for those of you who are concerned about using medication with kids) but the results are not as good and eventually the salt saturates the water and makes it cloudy.  Let me know if you try it with some other fizzy tablets such as Airborne.  Curious to see if those work just as well.

Follow this link to see where I got the idea from and more details about the experiment: http://slsmithphotography.typepad.com/my_weblog/2010/06/lava-lamps-summer-fun.html