Proton-Based Transistor Could Let Machines Communicate With Living Things
UW News (09/20/11) Hannah Hickey
Researchers at the University of Washington have developed a transistor that uses protons, instead of electrons, to send information, which could enable electronic devices to communicate directly with living things. "We found a biomaterial that is very good at conducting protons, and allows the potential to interface with living systems," says Washington professor Marco Rolandi. A machine that was compatible with a living system could monitor body processes such as flexing muscles and transmitting brain signals. The prototype device is a field-effect transistor, a drain and source terminal for the current. "In our device, large bio-inspired molecules can move protons, and a proton current can be switched on and off, in a way that's completely analogous to an electronic current in any other field-effect transistor," Rolandi says. The device uses a modified form of the compound chitosan, originally extracted from squid pen, because it works very well at moving protons by absorbing water and forming many hydrogen bonds that the protons are able to easily move between. "So we now have a protonic parallel to electronic circuitry that we actually start to understand rather well," Rolandi says.
UW News (09/20/11) Hannah Hickey
Researchers at the University of Washington have developed a transistor that uses protons, instead of electrons, to send information, which could enable electronic devices to communicate directly with living things. "We found a biomaterial that is very good at conducting protons, and allows the potential to interface with living systems," says Washington professor Marco Rolandi. A machine that was compatible with a living system could monitor body processes such as flexing muscles and transmitting brain signals. The prototype device is a field-effect transistor, a drain and source terminal for the current. "In our device, large bio-inspired molecules can move protons, and a proton current can be switched on and off, in a way that's completely analogous to an electronic current in any other field-effect transistor," Rolandi says. The device uses a modified form of the compound chitosan, originally extracted from squid pen, because it works very well at moving protons by absorbing water and forming many hydrogen bonds that the protons are able to easily move between. "So we now have a protonic parallel to electronic circuitry that we actually start to understand rather well," Rolandi says.
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