If there’s one factor we people are good at, it is producing warmth: important quantities, and in lots of circumstances a lot of the vitality we generate and put into our techniques we lose as warmth, whether or not or not it’s our home equipment, our transportation, our factories, even our electrical grid.
“Waste heat is everywhere,” mentioned UC Santa Barbara mechanical engineering professor Bolin Liao, who makes a speciality of thermal science and renewable vitality. “Our power plants, our car exhaust pipes—there are so many places where we create excess heat waste.”
For the second, we’re pretty restricted as to how we are able to take advantage of out of this dissipating warmth. However Liao and UCSB colleagues, alongside collaborators from Ohio State College and College of Hong Kong, are making headway towards placing that warmth to make use of, with a first-time complete characterization of the thermoelectric properties of high-quality cadmium arsenide skinny movies.
“If we could harvest that waste heat then that would be fantastic,” he mentioned. “That would really increase our energy efficiency and it’s also a really sustainable energy source.”
The group’s analysis is revealed within the journal Superior Supplies.
A greater thermoelectric materials
“To obtain high efficiency, we need the material to conduct electricity well, conduct heat poorly and generate a high voltage for a given temperature difference,” Liao mentioned. Poor warmth conduction minimizes warmth dissipation whereas sustaining a temperature distinction throughout the fabric, leading to an electrical present enhanced by the fabric’s high-performing electrical conductivity. The voltage ensuing from a temperature gradient is called the Seebeck impact.
This mixture {of electrical} and thermal transport properties is good, however based on Liao, “very hard to achieve in practice.”
Enter cadmium arsenide (Cd3As2), a Dirac semimetal with promising transport properties, particularly, a low thermal conductivity and excessive electron mobility.
“We were pretty excited about this material, and we thought, ‘Okay, this is really a combination of these two great properties,'” Liao mentioned. “But there is only one problem. This problem was that in addition to good electric conduction and poor thermal conduction, you also need this material to be able to generate enough voltage under a temperature gradient.”
As a semimetal, cadmium arsenide is superb at conducting electrical energy very quickly, nevertheless it solely generates a really small Seebeck voltage. To create a helpful voltage, Liao defined, one would want to open up a band hole.
“You want this material to have a certain energy range where the electrons cannot conduct. That’s called a band gap,” he mentioned. Due to the hole, which basically blocks the free circulate of electrons, sufficient electrical “pressure” (a.ok.a. voltage) can construct up as a response to a temperature distinction throughout the fabric. In bulk cadmium arsenide crystals, there isn’t a band hole.
Luckily, the group had a bonus, within the type of UCSB supplies scientist Susanne Stemmer’s thin-film prowess. With experience in molecular beam epitaxy (MBE), Stemmer’s lab is ready to “grow,” molecule by molecule, high-quality supplies with thicknesses starting from a couple of nanometers to a number of micrometers. That is notably helpful within the case of cadmium arsenide, it seems, as there are properties on the floor of the fabric which might be distinct from these within the bulk of the crystal.
“One signature of topological insulators like this is that in addition to electron conducting states inside the bulk material, they have surface conducting channels,” Liao defined. “There are electrons that reside only on the surface of the material, and they can conduct electricity.”
To set the stage for these topological results, the Stemmer Lab created three high-quality movies grown by MBE of various thicknesses: 950 nm, 95 nm and 25 nm.
“The high mobilities of epitaxial cadmium arsenide films allow for revealing their topological nature via quantum transport measurements,” Stemmer defined.
The group discovered that the thinner the fabric, the extra proof there was of a band hole. And, the thinner the fabric, the extra the floor results dominate.
“Basically, if you go to very low dimensions, quantum mechanics starts to play a role, and you can actually open a band gap just by shrinking the size,” mentioned Liao, as a result of a phenomenon generally known as quantum confinement. In addition they discovered that the thinner the fabric, the upper the thermoelectric sensitivity (generally known as the Seebeck coefficient), leading to extra voltage in response to the temperature gradient, a response enhanced by seven instances in comparison with the state-of-the-art materials.
These quantum results have been discovered at near-zero temperatures, so though presently Cd3As2 skinny movies cannot be deployed for room-temperature or high-heat effectivity functions, Liao mentioned, they might be extra instantly helpful in cryogenic environments, which exist in lots of functions, equivalent to aerospace, medication and quantum computing.
“If you’re using a very efficient, solid-state material for cooling, you won’t need dangerous and polluting refrigerants,” he mentioned.
“Practically, it’s a very useful discovery for low-temperature, cryogenic, solid-state cooling,” he added, “but fundamentally, this work is more important because we demonstrate for the first time that this quantum confinement effect can enhance some thermoelectric properties, and also for the first time we isolated the contribution from surface states.”
Extra info:
Wenkai Ouyang et al, Extraordinary Thermoelectric Properties of Topological Floor States in Quantum‐Confined Cd3As2 Skinny Movies, Superior Supplies (2024). DOI: 10.1002/adma.202311644
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College of California – Santa Barbara
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First complete characterization of the extraordinary thermoelectric properties of cadmium arsenide skinny movies (2024, June 27)
retrieved 27 June 2024
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