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Brain Waves

Your brainwaves normally vary from a low vibrational state of about one Hz ('Hertz,' or vibrations per second) to a high of about 30 Hz. The highest-frequency vibrations, ranging from about 13 to 30 Hz, are called beta waves. When your brain is in a beta state, it's in a high state of alertness. Alpha waves are somewhat slower, from 8 to 13 Hz. If ...

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BrainWaves
Medicine

What Is Narcolepsy?

Narcolepsy is a sleep disorder than affects about 1 of every 2000 people worldwide. It usually starts in the teens or twenties, but it may begin in childhood. People who have it fall suddenly and ... Continue reading

WhatIsNarcolepsy
Biology

The Human Pancreas

The pancreas is a body organ that does some heavy lifting. It carries on two important functions relating to digestion and the regulation of blood sugar. The exocrine, the larger function, makes ... Continue reading

HumanPancreas
Astronomy

Saturn: The Basics

To ancient astronomers, Saturn was a wandering light near the edge of the known universe. The planet and its rings have been objects of beauty and wonder ever since Galileo noticed the 'cup handles' ... Continue reading

SaturnTheBasics
Biology

Steller Sea Lion Biology

The Steller sea lion (Eumetopias jubatus) is the largest member of the Otariid (eared seal) family. Males may be up to 325 cm (10-11 ft) in length and can weigh up to 1,100 kg (2,400 lb). Females are ... Continue reading

StellerSeaLionBiology

Liquid Crystal Communication

LiquidCrystalCommunicationThe Information Age rides on beams of carefully controlled light. Because lasers form the arteries of modern communications networks, dexterous manipulation of light underpins the two definitive technologies of our times: telecommunications and the Internet. Now researchers at Harvard University have developed a new way of steering and manipulating light beams. Using droplets of liquid crystals--the same substance in laptop displays--the scientists can make a pane of glass that quickly switches from transparent to diffracting and back again. When the pane is transparent a laser beam passes straight through, but when the pane is diffracting, it splits the beam, bending it in several new directions.

The change is triggered by applying an electric field, so the pane could easily be controlled by the electric signals of a computer, offering a powerful new way to steer beams of light. Beyond telecommunications, one could imagine this light-steering ability being useful in astronomy. For example, these liquid-crystal panes could be used in reverse to combine (rather than split) beams of light from multiple telescopes. Combining light from many telescopes, a technique called interferometery, is a good way to search for distant planets around other stars. Another application: a liquid crystal pane held in front of the mirror of a telescope could be used to 'unwrinkle' light that has passed through Earth's turbulent atmosphere. Such adaptive optics telescopes could gain a crystal-clear view of the heavens from Earth's surface.

Liquid crystals are a class of liquids whose molecules are more orderly than molecules in regular fluids. Because of this orderliness, when these liquids interact with light, they can affect the light like crystals do. Making droplets of liquid crystals is nothing new; the basic technology has been around since the mid-1980s. Today you can find such droplets in the window-walls of some executives' offices. With the flip of a switch, the office's transparent windows magically change to opaque walls somewhat like frosted glass.