ScienceIQ.com

318 Times as Massive as Earth

What is 318 times more massive than Earth? Jupiter, the fifth planet from the Sun (next in line after Earth and Mars). Jupiter is the largest planet in our Solar System. If you decided to take a Boeing 777 for a trip around Jupiter, it would take you over 21 days just to circle once around its equator and that is without the refueling stops. ...

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Jupiter
Astronomy

Catch A Shooting Star

A meteor, sometimes called a 'shooting star,' can be the brightest object in the night sky, yet meteoroids are the smallest bodies in the solar system that can be observed by eye. Wandering through ... Continue reading

ShootingStar
Biology

See You Later Crocodile, In A While Alligator

Name a reptile that is really big, has lots of teeth and has been around for millions and millions of years. If you guessed an alligator, you'd be right. If you guessed a crocodile, you'd also be ... Continue reading

SeeYouLaterCrocodile
Physics

Tick-Tock Atomic Clock

Modern navigators rely on atomic clocks. Instead of old-style springs or pendulums, the natural resonances of atoms -- usually cesium or rubidium -- provide the steady 'tick' of an atomic clock. The ... Continue reading

AtomicClock
Biology

Vampires

What flying creature can hop, leap, and turn somersaults? Another hint: it can fit in the palm of your hand and weighs about the same as a penny. One more hint: its entire diet is blood. Desmodus ... Continue reading

Vampires

A Shear Mystery

ShearMysteryEveryone has had problems with a ketchup bottle at one time or another. After struggling and only getting a few drops, a flood suddenly gushes out and buries your food. With perfect timing, the ketchup changes from a thick paste to a runny liquid. If you find yourself wondering 'why?' you're in good company. Physicists are puzzled, too.

Ketchup is one of many complex fluids - including whipped cream, blood, film emulsions, nail polish and some plastics - that share a property called 'shear thinning.' Normally thick like honey, they can become thin and flow like water when stirred or shaken. The phenomenon is common enough, yet scientists aren't sure why it happens.

The ketchup-like behavior of pure fluids at their critical point is still only theoretical. Even simulations using supercomputers can't prove the theory. Think of that the next time you whack the bottom of a ketchup bottle. Even supercomputers can't predict the outcome!