researchers at the
U.S. Department of Energy's Argonne National Laboratory reported the
creation of the world's thinnest flexible, see-through 2-D thin film transistors.
These transistors are just 10 atomic layers thick—that's about how much your fingernails grow per second.
Transistors are the basis of nearly all electronics. Their two settings—on or off—dictate the 1s and 0s of computer binary
language. Thin film transistors are a particular subset of these that
are typically used in screens and displays. Virtually all flat-screen
TVs and smartphones are made up of thin film transistors today; they
form the basis of both LEDs and LCDs (liquid crystal displays).
Read more at: http://phys.org/news/2014-05-flexible-transparent-thin-transistors-screens.html#jCp
Researchers at the U.S. Department of Energy's Argonne National Laboratory reported the creation of the world's thinnest flexible, see-through 2-D thin film transistors.These transistors are just 10 atomic layers thick—that's about how much your fingernails grow per second.
Transistors are the basis of nearly all electronics. Their two settings—on or off—dictate the 1s and 0s of computer binary
language. Thin film transistors are a particular subset of these that
are typically used in screens and displays. Virtually all flat-screen
TVs and smartphones are made up of thin film transistors today; they
form the basis of both LEDs and LCDs (liquid crystal displays).Read more at: http://phys.org/news/2014-05-flexible-transparent-thin-transistors-screens.html#jCp
These transistors are just 10 atomic layers thick—that's about how much your fingernails grow per second.
Transistors are the basis of nearly all electronics. Their two settings—on or off—dictate the 1s and 0s of computer binary language. Thin film transistors are a particular subset of these that are typically used in screens and displays. Virtually all flat-screen TVs and smartphones are made up of thin film transistors today; they form the basis of both LEDs and LCDs (liquid crystal displays).
To measure how good a transistor is, you measure its on-off ratio—how completely can it turn off the current?—and a property called "field effect carrier mobility," which measures how quickly electrons can move through the material.
"We were pleased to find that the on/off ratio is just as good as current commercial thin-film transistors," said Argonne postdoctoral scientist and first author Saptarshi Das, "but the mobility is a hundred times better than what's on the market today."
The team also tried bending the films to test what happens under stress. In most thin film transistors, the material starts to crack, which, as you might imagine, affects performance. "But in ours, the properties didn't change at all," Roelofs said. "The layers just slide and don't crack."
The transistors also maintained performance over a wide range of temperatures (from -320°F to 250°F), a useful property in electronics, which can run very hot.
To build the transistors, the team started with a trick that earned its original University of Manchester inventors the Nobel Prize: using a strip of scotch tape to peel off a sheet of tungsten diselenide just atoms thick.
"We chose tungsten diselenide because it provides the electron and hole conduction necessary for making transistors with logic gates and other p-n junction devices," said Argonne scientist and coauthor Anirudha Sumant.
Then they used chemical deposition to grow sheets of other materials on top to build the transistor layer by layer. The final product is 10 atomic layers thick.
Next, the team is interested in adding logic and memory to flexible films, so you could make not just a screen but an entire flexible and transparent TV or computer.
"However, more work needs to be done in developing large-area synthesis of tungsten selenide to realize the true potential for applications of our work," said Sumant.
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