Schematic illustration displaying the fabrication means of the CNT/BST foam with varied shapes. Results of the BST content material and annealing temperature on TE properties of the CNT/BST foams. Extremely improved zT vlaue of CNT/BST foam in comparison with pristine CNT foam. Credit score: Korea Analysis Institute of Chemical Expertise (KRICT)
A Korean analysis staff has developed a novel thermoelectric materials and generator (TEG) that leverages sponge-like carbon nanotube (CNT) constructions, enhancing the restrictions of natural thermoelectric supplies whereas retaining flexibility. The ensuing machine is anticipated to be helpful in powering small-scale wearable sensors by thermal power harvesting.
The analysis is published within the journal Carbon Power.
Led by Drs. Mijeong Han and Younger Hun Kang on the Korea Analysis Institute of Chemical Expertise (KRICT), the staff mixed carbon nanotubes with Bi0.45Sb1.55The3 (BST) in a porous foam construction to maximise thermoelectric efficiency.
Whereas typical thermoelectric supplies are sometimes metal-based and inflexible, using CNTs permits for mild weight and mechanical flexibility—though earlier makes an attempt have resulted in low thermoelectric efficiency and poor sturdiness.
To beat these challenges, the staff developed a proprietary fabrication method that transforms CNTs into bulk foams relatively than skinny movies. This was achieved by heating and solidifying a powder-filled mould to create a sponge-like construction.
A technique was additionally developed to uniformly distribute the thermoelectric BST particles throughout the foam’s pores, enhancing each mechanical stability and thermoelectric efficiency.
In consequence, the CNT/BST foam achieved a zT of seven.8 × 10-3—5.7 instances larger than that of pristine CNT foam. When utilized to a versatile thermoelectric generator and examined on a glass tube at a temperature distinction of 21.8 Ok, the machine generated output energy of 15.7 µW—sufficient to function wearable sensors.
The concave TEG conforming to a cylindrical glass tube. Output voltage of the concave TEG with totally different water temperatures within the glass tube. The water flowed for 10 s and stopped for 20 s. Simulated temperature distributions contained in the TE legs with hot-water and cold-water flows. Credit score: Korea Analysis Institute of Chemical Expertise (KRICT)
Sturdiness was confirmed by 10,000-cycle bending checks, with minimal efficiency loss. Furthermore, your complete fabrication course of takes simply 4 hours, in comparison with over three days for conventional CNT-based TEGs, highlighting the fabric’s glorious scalability.
The staff plans to additional improve thermoelectric effectivity by doping methods and goals for commercialization by 2030. Future functions embody integration into thermal administration techniques for batteries and AI knowledge facilities, in addition to wearable and autonomous digital gadgets.
“This study represents a significant step forward in developing flexible, self-powered devices,” mentioned the researchers, including that the fabric’s moldability and sturdiness open new frontiers in power harvesting.
Extra data:
Myeong Hoon Jeong et al, Excessive‐efficiency and versatile thermoelectric generator based mostly on a sturdy carbon nanotube/BiSbTe foam, Carbon Power (2024). Two: 10.1002/CEY2.650
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Sponge-like carbon nanotube thermoelectric generator simply molds to advanced shapes and powers sensors (2025, April 29)
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