Thomas Edison discovered this when experimenting with light bulbs. He discovered that when an electric contacts are introduced to both ends, the current jumps from the hot filament of the bulb to a metal plate at the bottom. This is called the Edison Effect.
The Edison Effect or Thermal Electron Emission basically says that electric current can travel through a gas or a vacuum without the need of an electric wire to move through.
The vacuum tube found its use in 1904 when John A. Fleming invented the Diode. A diode is the most simple vacuum tube. It is basically a light bulb with an electrode inside it. The diode works when the bulb's filament is heated white hot and electrons are boiled off its surface and into the vacuum inside the bulb. If the extra electrode is made more positive than the hot filament, a direct current flows through the vacuum to the anode.
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| Diode |
Lee De Forest followed with his invention of the Audion. This type of vacuum tube performs like a diode but additionally also increases the current along the way. This is done by placing a metal grid in the middle of the vacuum and using a small input current to change the voltage on the grid. An audion can control the flow of the second more powerful current through the tube. The strength of the two currents need not to be related; a weak current can be applied to the tube's grid while a much stronger one can come out the main electrodes of the tube.
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| Triode |
The invention of the triode ushered in the Electronic Revolution of the 20th century.
Smaller, cheaper, efficient and reliable solid state semiconductor devices such as transistors and solid state diodes have replaced vacuum tubes in modern devices. But some applications still need the use of vacuum tubes such as High Power Radio Frequency Transmitters and Microwave Ovens.
In the music industry, professional musicians still prefer vacuum tube based sound amplifiers because of the quality of sound it produces.
Pitt researchers propose new spin on old method to develop more efficient electronics
With the advent of semiconductor transistors—invented in 1947 as a replacement for bulky and inefficient vacuum tubes—has come the consistent demand for faster, more energy-efficient technologies. To fill this need, researchers at the University of Pittsburgh are proposing a new spin on an old method: a switch from the use of silicon electronics back to vacuums as a medium for electron transport—exhibiting a significant paradigm shift in electronics. Their findings were published online in Nature Nanotechnology July 1.
For the past 40 years, the number of transistors placed on integrated circuit boards in devices like computers and smartphones has doubled every two years, producing faster and more efficient machines. This doubling effect, commonly known as "Moore's Law," occurred by scientists' ability to continually shrink the transistor size, thus producing computer chips with all-around better performance. However, as transistor sizes have approached lower nanometer scales, it's become increasingly difficult and expensive to extend Moore's Law further.
