‘Solar steam’ so effective it can make steam from icy cold water
Rice University scientists have unveiled a revolutionary new technology that uses nanoparticles to convert solar energy directly into steam. The new “solar steam” method from Rice’s Laboratory for Nanophotonics (LANP) is so effective it can even produce steam from icy cold water.
Details of the solar steam method were published online today in ACS Nano. The technology has an overall energy efficiency of 24 percent. Photovoltaic solar panels, by comparison, typically have an overall energy efficiency around 15 percent. However, the inventors of solar steam said they expect the first uses of the new technology will not be for electricity generation but rather for sanitation and water purification in developing countries.
“This is about a lot more than electricity,” said LANP Director Naomi Halas, the lead scientist on the project. “With this technology, we are beginning to think about solar thermal power in a completely different way.”
The efficiency of solar steam is due to the light-capturing nanoparticles that convert sunlight into heat. When submerged in water and exposed to sunlight, the particles heat up so quickly they instantly vaporize water and create steam. Halas said the solar steam’s overall energy efficiency can probably be increased as the technology is refined.
“We’re going from heating water on the macro scale to heating it at the nanoscale,” Halas said. “Our particles are very small — even smaller than a wavelength of light — which means they have an extremely small surface area to dissipate heat. This intense heating allows us to generate steam locally, right at the surface of the particle, and the idea of generating steam locally is really counterintuitive.”
To show just how counterintuitive, Rice graduate student Oara Neumann videotaped a solar steam demonstration in which a test tube of water containing light-activated nanoparticles was submerged into a bath of ice water. Using a lens to concentrate sunlight onto the near-freezing mixture in the tube, Neumann showed she could create steam from nearly frozen water.
Steam is one of the world’s most-used industrial fluids. About 90 percent of electricity is produced from steam, and steam is also used to sterilize medical waste and surgical instruments, to prepare food and to purify water.
Most industrial steam is produced in large boilers, and Halas said solar steam’s efficiency could allow steam to become economical on a much smaller scale.
People in developing countries will be among the first to see the benefits of solar steam. Rice engineering undergraduates have already created a solar steam-powered autoclave that’s capable of sterilizing medical and dental instruments at clinics that lack electricity. Halas also won a Grand Challenges grant from the Bill and Melinda Gates Foundation to create an ultra-small-scale system for treating human waste in areas without sewer systems or electricity.
“Solar steam is remarkable because of its efficiency,” said Neumann, the lead co-author on the paper. “It does not require acres of mirrors or solar panels. In fact, the footprint can be very small. For example, the light window in our demonstration autoclave was just a few square centimeters.”
Another potential use could be in powering hybrid air-conditioning and heating systems that run off of sunlight during the day and electricity at night. Halas, Neumann and colleagues have also conducted distillation experiments and found that solar steam is about two-and-a-half times more efficient than existing distillation columns.
Halas, the Stanley C. Moore Professor in Electrical and Computer Engineering, professor of physics, professor of chemistry and professor of biomedical engineering, is one of the world’s most-cited chemists. Her lab specializes in creating and studying light-activated particles. One of her creations, gold nanoshells, is the subject of several clinical trials for cancer treatment.
For the cancer treatment technology and many other applications, Halas’ team chooses particles that interact with just a few wavelengths of light. For the solar steam project, Halas and Neumann set out to design a particle that would interact with the widest possible spectrum of sunlight energy. Their new nanoparticles are activated by both visible sunlight and shorter wavelengths that humans cannot see.
“We’re not changing any of the laws of thermodynamics,” Halas said. “We’re just boiling water in a radically different way.”
Paper co-authors include Jared Day, graduate student; Alexander Urban, postdoctoral researcher; Surbhi Lal, research scientist and LANP executive director; and Peter Nordlander, professor of physics and astronomy and of electrical and computer engineering. The research was supported by the Welch Foundation and the Bill and Melinda Gates Foundation.
“Our particles are very small — even smaller than a wavelength of light”
So what happens when we start churning out industrial quantities of these things and they spill, leak, or are dumped? It’s not going to be easy (or perhaps possible) to clean them up. Have we just created Ice-9??
I would be interested in knowing how much water can be desalinated in a day by this process, assuming a clear day in the mid lattitudes. A liter? 10 liters?
–Chuck
This is absolutely fascinating!!
How possible is it, this technology and process can be applied to the desalination of sea water? I recently concluded a practical-engineering study on harnessing the Agulhas Current – off the East Coast of my country, South Africa – with a view to augmenting our dwindling natural water supply, with desalinated sea water – using electrical power generated from the above harnessing.
If it’s possible to use this new technology for desalination purposes, I can foresee it being unnecessary to proceed as I had planned above – particularly as we have a super-abundance of sunlight here where I live – and the whole procedure can take place on dry land, once the seawater has been piped into the desalination plant(s), for processing.
I would like very much to be advised of whether Rice University will consider the possibility of applying their technology to the desalination process? – which I can then put forward to our Government as an “alternative methodology” to my paper on the Agulhas Current, I’ve already submitted to them. – and I can be reached by email at lenstevens@telkomsa.net for your kind contact, in this regard. Thank You!
I have a vision of “making even the deserts bloom” – with this amazing breakthrough!!
Warm regards, Len Stevens.
Why I love and respect both science and journalism. These ideas will change the world, empowering humans literally and figuratively. In an Earth-friendlier way than most other ways of creating steam. In a more efficient way than most other ways of creating either cleanliness or electricity. WOW!