Controlling heat like light
January 15, 2013
Thermal lattices, shown here, are one possible application of the newly developed thermocrystals. In these structures, where precisely spaced air gaps (dark circles) control the flow of heat, thermal energy can be “pinned” in place by defects introduced into the structure (colored areas). (Credit: Martin Maldovan/MIT)
An MIT researcher has developed a technique that provides a new way of manipulating heat, allowing it to be controlled much as light waves can be manipulated by lenses and mirrors.
The approach relies on engineered materials consisting of nanostructured semiconductor alloy crystals.
Heat is a vibration of matter — technically, a vibration of the atomic lattice of a material — just as sound is. Such vibrations can also be thought of as a stream of phonons — a kind of “virtual particle” that is analogous to the photons that carry light.
The new approach is similar to recently developed photonic crystals that can control the passage of light, and phononic crystals that can do the same for sound.
Hot sounds
The spacing of tiny gaps in these materials is tuned to match the wavelength of the heat phonons, explains Martin Maldovan, a research scientist in MIT’s Department of Materials Science and Engineering and author of a paper on the new findings published Jan. 11 in the journal Physical Review Letters.
“It’s a completely new way to manipulate heat,” Maldovan says. Heat differs from sound, he explains, in the frequency of its vibrations: Sound waves consist of lower frequencies (up to the kilohertz range, or thousands of vibrations per second), while heat arises from higher frequencies (in the terahertz range, or trillions of vibrations per second).
In order to apply the techniques already developed to manipulate sound, Maldovan’s first step was to reduce the frequency of the heat phonons, bringing it closer to the sound range. He describes this as “hypersonic heat.”
“Phonons for sound can travel for kilometers,” Maldovan says — which is why it’s possible to hear noises from very far away. “But phonons of heat only travel for nanometers [billionths of a meter]. That’s why you couldn’t hear heat even with ears responding to terahertz frequencies.”
Heat also spans a wide range of frequencies, he says, while sound spans a single frequency. So, to address that, Maldovan says, “the first thing we did is reduce the number of frequencies of heat, and we made them lower,” bringing these frequencies down into the boundary zone between heat and sound. Making alloys of silicon that incorporate nanoparticles of germanium in a particular size range accomplished this lowering of frequency, he says.
Reducing the range of frequencies was also accomplished by making a series of thin films of the material, so that scattering of phonons would take place at the boundaries. This ends up concentrating most of the heat phonons within a relatively narrow “window” of frequencies.
Following the application of these techniques, more than 40 percent of the total heat flow is concentrated within a hypersonic range of 100 to 300 gigahertz, and most of the phonons align in a narrow beam, instead of moving in every direction.
Applications
As a result, this beam of narrow-frequency phonons can be manipulated using phononic crystals similar to those developed to control sound phonons. Because these crystals are now being used to control heat instead, Maldovan refers to them as “thermocrystals,” a new category of materials.
These thermocrystals might have a wide range of applications, he suggests, including in improved thermoelectric devices, which convert differences of temperature into electricity. Such devices transmit electricity freely while strictly controlling the flow of heat — tasks that the thermocrystals could accomplish very effectively, Maldovan says.
Most conventional materials allow heat to travel in all directions, like ripples expanding outward from a pebble dropped in a pond; thermocrystals could instead produce the equivalent of those ripples only moving out in a single direction, Maldovan says.
The crystals could also be used to create thermal diodes: materials in which heat can pass in one direction, but not in the reverse direction. Such a one-way heat flow could be useful in energy-efficient buildings in hot and cold climates.
Other variations of the material could be used to focus heat — much like focusing light with a lens — to concentrate it in a small area. Another intriguing possibility is thermal cloaking, Maldovan says: materials that prevent detection of heat, just as recently developed metamaterials can create “invisibility cloaks” to shield objects from detection by visible light or microwaves.
Comments (15)
by Bob Blackledge
eugene (& others) should read the brief summary of the published article at:
http://www.materials360online.com/newsDetails/33860
by asiwel
Yes, this summary is also a good one .. reading the actual PRL paper is even more interesting. This is really good research work, very liable to have all kinds of practical payoffs as well, I’d think .. just the sort of thing MIT is very good at doing.
by Mr. Kirk
When looking for Type II or Type III civilizations (see Kardeshev), we look for an abundance of heat. I’ve always thought an advanced civilization wouldn’t produce the waist heat we expect. Perhaps ultra efficiency means not waisting any energy, heat or otherwise. This is a prime example of such technologies in their infancy.
by AZryan
waste, not waist.
by the_system
I see a contradiction to the 2nd law of thermodynamics, or am I wrong? If you can construct something like a heat lens or beam to focus heat you can create a hotspot of heat out of a material that has had a homogeneous heat distribution before, you make the heat to float from a could spot to a hot spot what contradicts the 2nd LoT. Especially when it is possible to make something like a heat diode! Couldn’t you make a computer that works with heat out of this? This would revolutionize our whole energy problems. So where is my thought fault?
by asiwel
Off-hand, I would doubt any conflict with the 2nd law of thermodynamics. After all, air conditioners “move” heat from cold areas to warmer areas … but they do “work” in the process, using at least as much energy (if 100% efficient) from outside the system as represented by the amount of heat “moved”. Here, it probably requires energy to create the meta material in the first place. Then, if some spots in it have, say, higher heat affinity than others, then that is where heat will accumulate. If too much accumulates, then the whole thing would melt. But, yes, on the other hand, there seems no reason with advances in this sort of technology that you could not build a computer or other types of devices such as “coherent heat beams” that work entirely on the basis of thermodynamics rather than electromagnetics. If fact, the mathematics modelling these sorts of systems is amazingly similar if not identical. After all, this article is about similarities between “sound” and “heat” and various kind of “phonons” of all sorts of sizes and wavelengths … duality metaphors pretty familiar these days.
by Vin
Good question. Answer is at wikipedia, Heat pump and refrigeration cycle.
by asiwel
Look up in the article summary. It says “Heat also spans a wide range of frequencies” .. so, yes, incoherent noise. But then they are “…Reducing the range of frequencies … This ends up concentrating most of the heat phonons within a relatively narrow “window” of frequencies” .. so now we have less incoherence … more of the heat energy concentrated into relatively few vibrational modes .. a heat “chord” if you will. But still another way of thinking about a “coherent heat beam” (without any matter around) is simply an infrared laser.
by asiwel
Sorry, this was a response to @eugene below
by donklemencic
The image that comes to mind is of layers of thermocrystals sandwiched between layers of dense heat-generating circuitry, rapidly removing the unwanted heat. Would that be a feasible use?
by asiwel
These were essentially my thoughts too. I tend to think of heat as energy or as thermal vibrational noise. This article about “reorganizing” heat, controlling its vibrational frequency – sort of a “taser” or teraser, rather than a maser or laser, or putting all of the energy in these spots and not in other spots, etc., seems to focus more on the mechanical or displacement aspects rather than the energetic aspects (i.e., treating heat as a wave rather than a phonon.) So, if you put a lot of heat in one spot, doesn’t that spot get awfully hot? If you have coherent heat (which, of course, is no longer “noise”), don’t you have a heat beam? Interesting, what you can do with meta-materials.
by eugene
“Coherent heat”? Heat is incoherent intrinsically. Indeed each vibration mode is coherent motion of atoms. Vibration modes may be complex but all different modes are independent/incoherent. If you start to think you can break the second law of thermodynamics by some strange material structure you are on the wrong way.
by asiwel
Hi, @eugene. Sorry but I seem to have put my reply/response in the wrong place above under @vin.
by Chrispium
Insulators for housing and clothing for arctic environments is an option too.
by Bri
It’s surprisingly simlar to the coherence of lasers. Heat ray gun anyone? If they can accomplish the same conversion with a less expensive material than germanium, it could be applied to a tremendous number of activities and processes. Just taking the heat loss from server farms and turning it into electricity would represent huge savings in energy.