OrganicTransistor
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The touch, the feel of cotton, the fabric of our... transistors
Transistors of all shapes and sizes form the foundation of just about every electronic gadget under the sun, and similarly, cotton clothing is a key component of a well-rounded wardrobe. It was only a matter of time before these two got together to form a fashion-forward future, and an international team of scientists have accomplished the trick by creating a transistor using fibers of cotton. Now, this isn't the first organic transistor, but cotton's plentiful, cheap, lightweight and sustainable nature make it a great choice for use as a substrate in carbon-based transistors. To get the fluffy white stuff ready to amplify and switch electric signals, it was conformally coated (to cover all the fiber's irregularities) with gold nanoparticles, semiconductive and conductive polymers in a super thin layer to preserve its wearability flexibility. The result was an active transistor that can be used in integrated circuits sewn into your shirt, socks, or even pantaloons, if you like. The future of fashion is right around the corner, folks, and in that future your pants are the PC.
IMEC creates flexible microprocessor with organic semiconductors -- computational clothing right around the corner
Organic semiconductors have been teasing us with the possibility of computationally-inclined clothing for years, but until now we could only dream about our pants being the computer. That dream is closer to reality than ever, as researchers from IMEC have created a cheap (potentially 1/10th the cost of silicon chips), bendable microprocessor by layering a plastic substrate, gold circuits, organic dielectric, and a pentacene organic semiconductor to create an 8-bit logic circuit with 4000 transistors. Executing 6 instructions per second, these things won't be challenging Watson any time soon, but the chips should prove useful in creating cheaper flexible displays and sensors to tell us whether that week-old chicken in the fridge has gone bad. The trick was to overcome individual organic transistors' variable switching voltage thresholds -- as opposed to silicon's predictable nature -- that eliminated the possibility of organic-based logic circuits previously. But by adding a second gate to each transistor, IMEC was able to control the electrical field in each to prevent unwanted switching and usher in the dawn of plastic processors. The zenith of nerd fashion can't be far behind.
