Tiny tunes: A nanoradio is a carbon nanotube anchored to an electrode, with a second electrode just beyond its free end.
Who: Alex Zet
tl, University of California,
Who: Alex Zet
tl, University of California, Berkeley Definition: At the core of the nanoradio is a single molecule that can receive radio signals.
Impact: Tiny radio devices could improve cell phones and allow communication between tiny devices, such as environmental sensors.
Context: New nanotech tools are allowing researchers to fabricate very small devices. The nanoradio is one of the latest.
If you own a sleek iPod Nano, you've got nothing on Alex Zettl. The physicist at the University of California, Berkeley, and his colleagues have come up with a nanoscale radio, in which the key circuitry consists of a single carbon nanotube.
Any wireless device, from cell phones to environmental sensors, could benefit from nanoradios. Smaller electronic components, such as tuners, would reduce power consumption and extend battery life. Nanoradios could also steer wireless communications into entirely new realms, including tiny devices that navigate the bloodstream to release drugs on command.
Miniaturizing radios has been a goal ever since RCA began marketing its pocket-sized transistor radios in 1955. More recently, electronics manufacturers have made microscale radios, creating new products such as radio frequency identification (RFID) tags. About five years ago, Zettl's group decided to try to make radios even smaller, working at the molecular scale as part of an effort to create cheap wireless environmental sensors.
Zettl's team set out to miniaturize individual components of a radio receiver, such as the antenna and the tuner, which selects one frequency to convert into a stream of electrical pulses that get sent to a speaker. But integrating separate nanoscale components proved difficult. About a year ago, however, Zettl and his students had a eureka moment. "We realized that, by golly, one nanotube can do it all," Zettl says. "Within a matter of days, we had a functioning radio." The first two transmissions it received were "Layla" by Derek and the Dominos and "Good Vibrations" by the Beach Boys.
The Beach Boys song was an apt choice. Zettl's nano receiver works by translating the electromagnetic oscillations of a radio wave into the mechanical vibrations of a nanotube, which are in turn converted into a stream of electrical pulses that reproduce the original radio signal. Zettl's team anchored a nanotube to a metal electrode, which is wired to a battery. Just beyond the nanotube's free end is a second metal electrode. When a voltage is applied between the electrodes, electrons flow from the battery through the first electrode and the nanotube and then jump from the nanotube's tip across the tiny gap to the second electrode. The nanotube--now negatively charged--is able to "feel" the oscillations of a passing radio wave, which (like all electromagnetic waves) has both an electrical and a magnetic component
Those oscillations successively attract and repel the tip of the tube, making the tube vibrate in sync with the radio wave. As the tube is vibrating, electrons continue to spray out of its tip. When the tip is farther from the second electrode, as when the tube bends to one side, fewer electrons make the jump across the gap. The fluctuating electrical signal that results reproduces the audio information encoded onto the radio wave, and it can be sent to a speaker.
The next step for Zettl and his colleagues is to make their nanoradios send out information in addition to receiving it. But Zettl says that won't be hard, since a transmitter is essentially a receiver run in reverse.
Nano transmitters could open the door to other applications as well. For instance, Zettl suggests that nanoradios attached to tiny chemical sensors could be implanted in the blood vessels of patients with diabetes or other diseases. If the sensors detect an abnormal level of insulin or some other target compound, the transmitter could then relay the information to a detector, or perhaps even to an implanted drug reservoir that could release insulin or another therapeutic on cue. In fact, Zettl says that since his paper on the nanotube radio came out in the journal Nano Letters, he's received several calls from researchers working on radio-based drug delivery vehicles. "It's not just fantasy," he says. "It's active research going on right now."
Any wireless device, from cell phones to environmental sensors, could benefit from nanoradios. Smaller electronic components, such as tuners, would reduce power consumption and extend battery life. Nanoradios could also steer wireless communications into entirely new realms, including tiny devices that navigate the bloodstream to release drugs on command.
Miniaturizing radios has been a goal ever since RCA began marketing its pocket-sized transistor radios in 1955. More recently, electronics manufacturers have made microscale radios, creating new products such as radio frequency identification (RFID) tags. About five years ago, Zettl's group decided to try to make radios even smaller, working at the molecular scale as part of an effort to create cheap wireless environmental sensors.
Zettl's team set out to miniaturize individual components of a radio receiver, such as the antenna and the tuner, which selects one frequency to convert into a stream of electrical pulses that get sent to a speaker. But integrating separate nanoscale components proved difficult. About a year ago, however, Zettl and his students had a eureka moment. "We realized that, by golly, one nanotube can do it all," Zettl says. "Within a matter of days, we had a functioning radio." The first two transmissions it received were "Layla" by Derek and the Dominos and "Good Vibrations" by the Beach Boys.
The Beach Boys song was an apt choice. Zettl's nano receiver works by translating the electromagnetic oscillations of a radio wave into the mechanical vibrations of a nanotube, which are in turn converted into a stream of electrical pulses that reproduce the original radio signal. Zettl's team anchored a nanotube to a metal electrode, which is wired to a battery. Just beyond the nanotube's free end is a second metal electrode. When a voltage is applied between the electrodes, electrons flow from the battery through the first electrode and the nanotube and then jump from the nanotube's tip across the tiny gap to the second electrode. The nanotube--now negatively charged--is able to "feel" the oscillations of a passing radio wave, which (like all electromagnetic waves) has both an electrical and a magnetic component
Those oscillations successively attract and repel the tip of the tube, making the tube vibrate in sync with the radio wave. As the tube is vibrating, electrons continue to spray out of its tip. When the tip is farther from the second electrode, as when the tube bends to one side, fewer electrons make the jump across the gap. The fluctuating electrical signal that results reproduces the audio information encoded onto the radio wave, and it can be sent to a speaker.
The next step for Zettl and his colleagues is to make their nanoradios send out information in addition to receiving it. But Zettl says that won't be hard, since a transmitter is essentially a receiver run in reverse.
Nano transmitters could open the door to other applications as well. For instance, Zettl suggests that nanoradios attached to tiny chemical sensors could be implanted in the blood vessels of patients with diabetes or other diseases. If the sensors detect an abnormal level of insulin or some other target compound, the transmitter could then relay the information to a detector, or perhaps even to an implanted drug reservoir that could release insulin or another therapeutic on cue. In fact, Zettl says that since his paper on the nanotube radio came out in the journal Nano Letters, he's received several calls from researchers working on radio-based drug delivery vehicles. "It's not just fantasy," he says. "It's active research going on right now."
Tiny TunesA nanoradio is a carbon nanotube anchored to an electrode, with a second electrode just beyond its free end. When a voltage is applied between the electrodes, electrons flow from a battery through the nanotube, jumping off its tip to the positive electrode. A radio wave alternately attracts and repels the nanotube tip, causing it to vibrate in sync. When the tip is farther from the electrode, fewer electrons bridge the gap; the varying electrical signal recovers the audio signal encoded by the radio wave.Credit: John Hersey
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