Nano antenna concentrates light: Intensity increases 1,000-fold

Sep 20, 2010
This artist's rendering shows how plasmons in a pair of gold nanotips concentrate light from a laser, amplifying it by a factor of 1,000. Credit: Natelson Lab/Rice University

(PhysOrg.com) -- Everybody who's ever used a TV, radio or cell phone knows what an antenna does: It captures the aerial signals that make those devices practical. A lab at Rice University has built an antenna that captures light in the same way, at a small scale that has big potential.

Condensed matter physicist Doug Natelson and graduate student Dan Ward have found a way to make an optical antenna from two gold tips separated by a nanoscale gap that gathers light from a laser. The tips "grab the light and concentrate it down into a tiny space," Natelson said, leading to a thousand-fold increase in in the gap.

Getting an accurate measurement of the effect is a first, said Natelson, who reported the results in today's online edition of the journal Nature Nanotechnology. He expects the discovery will be useful in the development of tools for optics and for chemical and biological sensing, even at the single-molecule scale, with implications for industrial safety, defense and homeland security.

The paper by Natelson, Ward and their colleagues in Germany and Spain details the team's technique, which involves shining into the gap between a pair of gold tips less than a nanometer apart - about a hundred-thousandth the width of a human hair.

"You can ignore the fact that your car antenna is built out of atoms; it just works," said Natelson, a Rice professor of physics and astronomy, and also electrical and computer engineering. "But when you have tiny pieces of metal very close to each other, you have to worry about all the details. The fields are going to be big, the situation's going to be complicated and you're really constrained. We've been able to use some physics that only come into play when things are very close together to help figure out what's going on."

The key to measuring turned out to be measuring something else, specifically the electrical current flowing between the gold tips.

Putting the nanotips so close together allows charge to flow via quantum tunneling as the electrons are pushed from one side to the other. The researchers could get electrons moving by pushing them at low frequencies with a voltage, in a highly controllable, measurable way. They could also get them flowing by shining the laser, which pushes the charge at the very high frequency of the light. Being able to compare the two processes set a standard by which the light amplification could be determined, Natelson said. Their German and Spanish coauthors helped supply the necessary theoretical justification for the analysis.

The amplification is a plasmonic effect, Natelson said. Plasmons, which may be excited by light, are oscillating electrons in metallic structures that act like ripples in a pool. "You've got a metal structure, you shine light on it, the light makes the electrons in this metal structure slosh around," he said. "You can think of the electrons in the metal as an incompressible fluid, like water in a bathtub. And when you get them sloshing back and forth, you get electric fields.

Nano antenna concentrates light
This is a colorized scanning electron microscope image of gold tips in a nanogap device used in experiments to capture and amplify light. Credit: Natelson Lab/Rice University

"At the surfaces of the metal, these fields can be very big - much bigger than those from the original radiation," he said. "What was hard to measure was just how big. We didn't know how much the two sides were sloshing up and down - and that's exactly the thing we care about."

By simultaneously measuring the low-frequency electrically driven and the high-frequency optically driven currents between the tips, "we can figure out the voltage zinging back and forth at the really high frequencies that are characteristic of ," he said.

Natelson said his lab's homebuilt apparatus, which combines nanoscale electronics and optics, is fairly unusual. "There are a lot of people who do optics. There are a lot who do nanoscale electrical measurements," he said. "There are still not too many people who combine the two."

The custom rig gave the Rice researchers a measure of control over thermal and electrical properties that have stymied other investigators. The tips are cooled to 80 Kelvin, about -315 degrees Fahrenheit, and are electrically insulated from their silicon bases, keeping at bay stray voltages that could skew the results.

"The reason we're studying these enhanced fields is not just because they're there," Natelson said. "If you can enhance the local field by a factor of 1,000, there are lots of things you can do in terms of sensors and non-linear optics. Anything that gives you a handle on what's happening at these tiny scales is very useful.

"This is one of those rare, happy cases where you are able to actually get information - very local information - about exactly something you care about."

Explore further: Nanotube cathode beats large, pricey laser

More information: www.nature.com/nnano/journal/v… /nnano.2010.176.html

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labtvonline
5 / 5 (1) Sep 20, 2010
I'm curious to know if they are thinking of using this technology to amplify the light coming into some of today's highly efficient solar panels like the one in this video which is over 10,000 times more efficient than our current solar standard.
http://www.ndep.u...ll-World
Husky
5 / 5 (1) Sep 20, 2010
another application using tiny slits
http://www.scienc...dfetcher
maxcypher
not rated yet Sep 20, 2010
It's refreshing to see a (100nm scale) picture of the rough material scientists actually have to work with, rather than the smooth, idealized pictures that illustrators come up with in these articles.
dirk_bruere
not rated yet Sep 20, 2010
So how big are the fields?
Koen
not rated yet Sep 21, 2010
Maybe a better description is 'optical transistor'. An 'antenna' translates electromagnetic fields into currents. In this particular case, there is a tunneling of electrons, and the tunneling current is not further used for amplification by common electronics in order to get a signal for human consumption.

My first thought to use this effect: quantum computing on mesa-scale (not the scale of 1 elementary particle, and not the scale of micro-electronics).
This optical transistor might enable ultra fast computing on a very small scale. Open questions: can the amplified fields be used to trigger a second tunneling gap? Is it possible to engineer an 'inverse' effect of this amplification? Maybe it is possible to keep the 'gap' in strong-field state, even after switching of the laser.

The first quantum computers will make use of 'collective' quantum behaviour of multiple particles (like tunneling electrons) on mesa scale, that's for sure. This experiment looks right to me.
Quantum_Conundrum
not rated yet Sep 25, 2010
Might this be useful in digital cameras, microscopes, and telescopes?

On a side note, it seems a very high number of recent nanotech discoveries involve Gold. It would seem that the value of Gold might be expected to go up significantly not as a mere "currency" or buffer against inflation, but as a primary component in a new generation of technologies over the next several decades.