05-03-2010
The rain dance is getting a twenty-first-century revamp using laser technology. Optical physicists have demonstrated that shooting lasers into the air can trigger the formation of water droplets, a technique that could one day help to stimulate rainfall.
For more than 50 years, efforts to try to artificially induce rain have concentrated on 'cloud seeding' — scattering small particles of silver iodide into the air to act as 'condensation nuclei', or centres around which rain droplets can grow. "The problem is, it's still not clear that cloud seeding works efficiently," says optical physicist Jérôme Kasparian at the University of Geneva, Switzerland. "There are also worries about how safe adding silver iodide particles into the air is for the environment."
Kasparian and his colleagues realized that there might be a more environmentally friendly alternative. Firing a laser beam made up of short pulses into the air ionizes nitrogen and oxygen molecules around the beam to create a plasma, resulting in a 'plasma channel' of ionized molecules. These ionized molecules could act as natural condensation nuclei, Kasparian explains.
To test whether this technique could induce droplets, the researchers fired a high-powered laser through an atmospheric cloud chamber in the lab containing saturated air. They illuminated the chamber using a second, standard low-power laser, enabling them to see and measure any droplets produced. Immediately after the laser was fired, drops measuring about 50 micrometres wide formed along the plasma channel. Over the next three seconds, the droplets grew in size to 80 micrometres as the smaller droplets coalesced. The team's results are published online in Nature Photonics 1.
Rainmaker
The next step for Kasparian and his team was to take the technique outside. The researchers already have experience using plasma channels to modify the weather: in 2008, they demonstrated that a beam from their high-powered portable 'Teramobile laser' could be fired into thunder clouds, triggering an electric discharge2. The beam was able to reach its target without being deflected because the generated plasma channel modifies the speed at which light travels through air — slowing it down in the centre of the beam and speeding it up at the sides. This causes the beam to continually self-focus, helping it to maintain a high intensity across large distances (see 'Bendy laser beam fired through the air').
This time, Kasparian and his colleagues tested the Teramobile laser over a number of different nights and in various humidity conditions. Once again, they detected the amount of condensation induced by monitoring how much the light from a second laser was back-scattered by any droplets. In low humidity conditions, the Teramobile laser did not induce droplets. But when the humidity was high, the team measured up to 20 times more back-scattering after the Teramobile laser was fired than before, says Kasparian, suggesting that condensation droplets were forming.
Roland Sauerbrey, an expert on laser physics at the FZD Dresden–Rossendorf Research Centre in Dresden, Germany, says that the team has the potential to create a "breakthrough technology". "This is the first time that a laser has been used to cause condensation outdoors," he says.
However, the technique is still in its early stages. "We can only create condensation along the laser channel, so we won't be going out and making rain tomorrow," Kasparian notes. He and his team are now investigating whether they can create condensation over a wider area, by sweeping their laser across the sky.
Thomas Leisner, an atmospheric physicist at the Karlsruhe Institute of Technology, Germany, remains cautious about the feasibility of scaling up the technique in this way. "I am sceptical that this could be used to trigger rain on demand," he says. But he adds that the technology will have other uses. The researchers should now calibrate the relationship between the amount of condensation produced by the laser and the prevailing atmospheric conditions, he says. "They could use the amount of condensation produced by their laser as a measure of water saturation to help forecast the chance of rain," he says.
References
Rohwetter, P. et al. Nature Photonics advance online publication doi:10.1038/nphoton.2010.115 (2010).
Kasparian, J. et al. Opt. Express 16, 5757-5763 (2008).
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