Orlando Science Center's exhibit halls feature a vast array of exciting interactive experiences! Learning has never been so fun with these hands on educational exhibits. From down to earth explorations in natural science to the high-tech world of simulation technology, everywhere you look, you'll find educational and entertaining opportunities to explore, experiment, and discover.
The Orlando Science Center is home to some of the most exciting traveling exhibits in the country. Upcoming traveling exhibits at the Science Center include Blue Man Group – Making Waves and Adventures With Clifford: The Big Red Dog. When these exhibits are in town they are only here for a limited time; so don’t miss the opportunity to see them!
As great as our traveling exhibits are, there are some exhibits that are the staple of the Orlando Science Center. NatureWorks will have you up close and personal with some of nature’s most fascinating reptiles. At DinoDigs, you’ll step back into the prehistoric age. Discover the dynamic forces and systems that shape our Earth, as well as other planets in Our Planet, Our Universe. Explore such concepts as electricity and magnetism, lasers, soundwaves, and nature’s forces in Science Park. No visit to the Science Center is complete without a trip to KidsTown, an interactive world dedicated to our smaller explorers.
Science Live! Programs
What’s the difference between a great visit to a Science Center and a memorable visit? Live programs. Our exhibits are designed to inspire curiosity and exploration, our Science Live! programs are designed to bring the exhibits to life. Whether it’s a show in the Digital Adventure Theater or a one-to-one interaction with a volunteer at the Crosby Observatory, our live programs create the kind of impact that can last a lifetime.
Looking for little more “hard science” in your next Science Center visit? Look no further than the Science Stations located throughout the facility. Science Stations are a cross between exhibits and live programs in that they’re exhibits that typically include a live program to truly bring the experience to life. Science Stations provide an in-depth look at their respective subject matter in an entertaining way. Be sure to check your program schedule to see which Science Stations are conducting demonstrations on the day of your next visit.
The aluminum-domed Crosby Observatory atop Orlando Science Center houses Florida's largest publicly accessible refractor telescope. This one-of-a-kind custom-built telescope, along with several smaller scopes, are available at selected times for solar and night sky viewing.
Solar storms may be a problem of the past due to prevention in the future. For the first time ever, scientist are able to see a 360-degree panorama view of the sun! NASA released these images in early February, recorded from the Solar Dynamic Observatory with those from NASA’s twin STEREO spacecraft. Scientists are now embarking on an 8-year exploration, primarily to look at the rotating sun’s far side. The goal is to be able to better predict solar storms.
A solar storm is an electrified gas cloud that erupts from the surface of the sun into space, which can damage satellites and disrupt communication systems on earth. Scientists hope that being able to predict the future of solar storms will help them find a way to prevent them. For the first time ever, the video below allows us to watch solar activity in its full 3-D dimensional glory. The video shows us a 360-degree panorama view of the sun and then zooms in on a solar eruption.
Take the time to learn about the letter B while making this simple Mardi Gras mask. This will certainly show the little ones in your family that learning can be fun. The letter B is the perfect shape to make a mask so why not take this time to teach them the importance of knowing their letters and sounds. Your family will be ready for Mardi Gras in no time; with great fashion and originality when you are done with this craft.
Construction paper or colored printable card stock
Craft stick or drinking straw
Make alphabet letters on your mask with any of these:
Alphabet stickers/stamps,or draw letters with crayons
Draw the letter "B" on construction paper. Make sure the size is just right for you to wear it as a mask. You may also opt to print out this template on colored card stock instead.
Cut the letter "B". You may need an adult's help in cutting out the eyeholes.
Decorate the front side of the mask with alphabet letters. Stick alphabet stickers, use alphabet stamps or write the letters using crayons.
Tape a craft stick or a drinking straw at the back to make the handle.
Tape feathers and/or curly ribbons at the back as well. Click here on how to make your own curly ribbons.
The Kepler mission hit another home run with the discovery of 1,235 possible new planets in the galaxy! These “exo” or “extra” planets are scattered across the Milky Way— large and small—orbiting stars other than the sun. Wondering how the Kepler spacecraft works? This planet locater is actually a telescope that follows the earth around its orbit of the sun, recording what it sees. The Kepler telescope is always pointed at the same area in the sky, so when there are changes in the starlight, it shows that a planet is close at hand. When the planet passes by the telescope, the light will dim and then return to normal. According to Science News, this will allow scientists to begin composing a galactic planetary census which will show how many planets are in the galaxy.
NASA’s quest to find a planet that inhabits life is currently in full swing, more than ever before. This discovery gives scientists new and original locations to hunt, causing an astronomy frenzy! Scientist will be looking at locations where the exoplanets orbit around a star, allowing the perfect temperature for life, creating a habitable or “goldilocks” zone—not too hot, not too cold, but just right.
There are now 54 prospective planets in that zone, the smallest are about the size of Earth. This is a new chapter for scientist in the field of astronomy, in the search to find another earth-like planet.
Ever wonder how a cloud is formed? Try this experiment to find out. You can make your own homemade cloud by using simple ingredients. A cloud needs three basic ingredients to be formed, water vapor; dust, smoke or other particles in the air; and a drop in air pressure. With all these ingredients present you can create a cloud, even at home! This experiment involves matches, so kids - don't try this without an adult!
2-liter clear plastic pop bottle
matches (children will need adult assistance to light matches)
Fill the clear plastic 2-liter bottle one-third full of warm water and place the cap on. As warm water evaporates, it adds water vapor to the air inside the bottle. This is the first ingredient to make a cloud.
Squeeze and release the bottle and observe what happens. You’ll notice that nothing happens. Why? The squeeze represents the warming that occurs in the atmosphere. The release represents the cooling that occurs in the atmosphere. If the inside of the bottle becomes cover with condensation or water droplets, just shake the bottle to get rid of them.
Take the cap off the bottle. Carefully light a match and hold the match near the opening of the bottle.
Then drop the match in the bottle and quickly put on the cap, trapping the smoke inside. Dust, smoke or other particles in the air is the second ingredient to make a cloud.
Once again, slowly squeeze the bottle hard and release. What happens? A cloud appears when you release and disappears when you squeeze. The third ingredient in clouds is a drop in air pressure.
Water vapor, water in its invisible gaseous state, can be made to condense into the form of small cloud droplets. By adding particles such as the smoke enhances the process of water condensation and by squeezing the bottle causes the air pressure to drop. This creates a cloud!
The traditional laser has been turned inside out, producing what scientist like to call an “anti-laser”. This device is actually called a coherent perfect absorber and has the capabilities to absorb rather than release a stream of light.
In a traditional laser, energy is injected into a medium that is transferred between two mirrors while stimulating photons, which are then reflected back through the mirrors, resulting in an amplification of light. The anti-laser works in a similar fashion, except the medium contains an absorptions component instead of amplification one. Scientists believe the anti-laser has the potential to be used in fields such as computing and medical imaging; leading to instrumental advances in technology. This innovational physics device was discovered by scientist at Yale University and has been noted as a surprising and exciting achievement in the science community.