First author Monisha Vijay Kumar, a
graduate student in applied physics at Rice. Credit: Jorge Vidal/Rice University
A
cross-disciplinary team at Rice University has developed a new type of electric
heating element—one that looks less like a traditional metal coil and more like
a high-performance thread. In a study published in Small, the researchers demonstrated that wires and fabrics
made from carbon nanotube fibers (CNTFs) can deliver substantially more heating
power per unit mass than conventional metal-alloy heaters when placed directly
in flowing gases. The findings point to a potential new pathway for
electrifying industrial heating, a critical but technically challenging step
toward reducing carbon emissions.
"Electrifying industrial heat is
one of the most important, and most difficult, pieces of decarbonization,"
said first author Monisha Vijay Kumar, a graduate student in applied physics.
"We wanted to understand whether an entirely different class of materials
could expand what's possible in gas heating."
Industrial facilities routinely heat gases for processes ranging from chemical production and drying to thermal treatment and manufacturing. Today, that heat is typically generated by burning fuels. While electric heating may sound like a simple replacement—passing current through a resistive element—heating moving gases imposes severe demands on materials and design. Heaters must transfer energy rapidly and evenly into the gas stream while avoiding destructive hot spots, mechanical deformation and failure under extreme temperatures. Placing heating elements directly in the gas flow (a strategy known as immersion heating) improves efficiency but significantly increases stress on the material.
"When you
immerse a heater directly into a gas stream, you gain heat-transfer efficiency,
but you also create a much harsher operating environment," said Daniel J.
Preston, assistant professor of mechanical engineering, whose lab studies
high-performance thermal management systems. "Geometry, stability and
performance all become tightly coupled."
One of the
most stubborn constraints is size. Thinner heating elements exchange heat with
gases more effectively, but conventional metal alloys are difficult to
fabricate and handle at very small diameters. CNTFs offer a striking
alternative; they combine electrical resistivity suitable for Joule heating
with exceptional strength-to-weight ratios and unusually high thermal
conductivity compared with traditional heater materials.
"Carbon
nanotube fibers behave very differently from metal wires," said Matteo
Pasquali, the A.J. Hartsook Professor of Chemical and Biomolecular Engineering
and director of the Carbon Hub. "They are lightweight, flexible and
remarkably strong, which allows us to consider heater geometries and
fabrication techniques that would be impractical with conventional
materials."
New architectures enabled by CNT fibers
Rather than
adapting CNTFs to existing heater designs, the team built devices made entirely
from the fibers, including single filaments, parallel arrays and textilelike
fabrics. Their key performance metric was specific power loading—the maximum
heating power per unit mass a device can sustain before failure.
Across
multiple configurations and operating conditions, CNTF heaters consistently
achieved higher specific power loadings than comparable metal-alloy elements.
The advantage was particularly pronounced in nonoxidizing environments, where
carbon-based materials can withstand far higher temperatures without
degradation. From a heat-transfer perspective, the fibers' thermal properties
proved especially important.
"Their high thermal conductivity helps
distribute heat and suppress localized hot spots, which are a common cause of
heater failure," said Geoff Wehmeyer, assistant professor of mechanical
engineering and an expert in nanoscale heat transport. "That heat
spreading fundamentally changes how these devices behave under extreme
conditions."
The study
highlights the fact that performance gains arise not only from material
properties but also from the new architectures those properties enable. CNTFs
can be produced at extremely small diameters while retaining mechanical
robustness, opening design possibilities that are difficult to achieve with
metal wires.
"Materials
only become impactful when you can reliably build with them," Pasquali
said. "CNTFs provide unusual flexibility: For example, you can tie a knot
in them and they don't break; this expands the available design space."
Textile-inspired manufacturing approaches
A distinctive
feature of the work is its reliance on textile-inspired manufacturing
techniques. CNTF yarns can be woven, knitted and assembled into lightweight,
high-surface area structures—geometries that are particularly well suited for
immersion heating. Vanessa Sanchez, assistant professor of mechanical
engineering, contributed expertise in advanced manufacturing and textile
technologies that helped translate nanoscale fibers into device-scale systems.
"Textile
techniques give us extraordinary freedom in creating three-dimensional
architectures," Sanchez said. "We can design heaters that are
lightweight, porous and mechanically compliant while remaining electrically
functional."
Compared with rigid metal meshes, CNTF fabrics exhibited more uniform heating behavior and reduced hot spot formation, benefits again linked to the fibers' ability to spread heat efficiently.
From left to right, Daniel J. Preston;
Hung-Yu "Iris" Lin, a PhD student in Preston's lab and part of the
research team; Vanessa Sanchez; Monisha Vijay Kumar; Geoff Wehmeyer and Matteo
Pasquali. Credit: Jorge Vidal, Rice University
Collaboration from lab to industry
The project represents an unusual
convergence of research communities, bringing together materials synthesis,
nanoscale heat-transfer science, device engineering and manufacturing. The
research also benefited from close collaboration with industrial researchers
Robert Headrick and Dhruv Arora at Shell and with the research team at DexMat,
which has commercialized and scaled up the CNTF production.
"This work required multiple layers of expertise," Wehmeyer said. "Producing high-quality CNTFs is only the starting point. Understanding how they perform thermally and integrating them into functional devices is equally important."
Source: Carbon nanotube fiber 'textile' heaters could help industry electrify high-temperature gas heating
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