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Main Authors: Tewani, Hridyesh, Scheerer, Vincent, Owens, Madison, Cumbajin, Emilio, De Leon, Camila, Hussain, MD Rashid, Ravindranath, Pruthul Kokkada, Van Lear, Rachel, Jack, David, Wallace, David, Prabhakar, Pavana
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.01145
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author Tewani, Hridyesh
Scheerer, Vincent
Owens, Madison
Cumbajin, Emilio
De Leon, Camila
Hussain, MD Rashid
Ravindranath, Pruthul Kokkada
Van Lear, Rachel
Jack, David
Wallace, David
Prabhakar, Pavana
author_facet Tewani, Hridyesh
Scheerer, Vincent
Owens, Madison
Cumbajin, Emilio
De Leon, Camila
Hussain, MD Rashid
Ravindranath, Pruthul Kokkada
Van Lear, Rachel
Jack, David
Wallace, David
Prabhakar, Pavana
contents Carbon fiber-reinforced polymers (CFRPs) have been extensively used in the aerospace and wind energy industries due to their superior specific mechanical properties and corrosion resistance. However, their higher electrical resistivity makes them susceptible to lightning strike damage, which necessitates the addition of a surface lightning strike protection (LSP) layer. Traditional LSP systems, such as copper mesh or expanded foil, reduce lightning strike damage, but are not easily drapable around complex geometries and may introduce delamination-prone regions within the composite. Here, we propose a novel manufacturing strategy for architected hybrid composites as drapable LSP by weaving stainless steel yarns within the woven carbon fiber composites. We varied the metal-to-carbon yarn ratio and stacking configuration to assess damage evolution under quasi-static arc exposures and simulated lightning strikes. Our results elucidate that incorporating hybrid layers into composites significantly reduced surface temperatures, through-thickness damage, and mass loss under both electric arc impacts. The composites with the proposed LSP layers also exhibited higher retention of flexural modulus and strength compared to the reference CFRP. Advanced air mobility (AAM) vehicles, which operate at lower altitudes, face significant safety challenges due to their high susceptibility to lightning strikes. Therefore, the proposed hybridized composites can be used as an efficient and drapable LSP around complex shapes in AAM vehicles, offering enhanced safety and protection.
format Preprint
id arxiv_https___arxiv_org_abs_2511_01145
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Ar$χ$i-Textile Composites: Drapable Hybrid Woven Composites for Lightning Strike Protection
Tewani, Hridyesh
Scheerer, Vincent
Owens, Madison
Cumbajin, Emilio
De Leon, Camila
Hussain, MD Rashid
Ravindranath, Pruthul Kokkada
Van Lear, Rachel
Jack, David
Wallace, David
Prabhakar, Pavana
Applied Physics
Carbon fiber-reinforced polymers (CFRPs) have been extensively used in the aerospace and wind energy industries due to their superior specific mechanical properties and corrosion resistance. However, their higher electrical resistivity makes them susceptible to lightning strike damage, which necessitates the addition of a surface lightning strike protection (LSP) layer. Traditional LSP systems, such as copper mesh or expanded foil, reduce lightning strike damage, but are not easily drapable around complex geometries and may introduce delamination-prone regions within the composite. Here, we propose a novel manufacturing strategy for architected hybrid composites as drapable LSP by weaving stainless steel yarns within the woven carbon fiber composites. We varied the metal-to-carbon yarn ratio and stacking configuration to assess damage evolution under quasi-static arc exposures and simulated lightning strikes. Our results elucidate that incorporating hybrid layers into composites significantly reduced surface temperatures, through-thickness damage, and mass loss under both electric arc impacts. The composites with the proposed LSP layers also exhibited higher retention of flexural modulus and strength compared to the reference CFRP. Advanced air mobility (AAM) vehicles, which operate at lower altitudes, face significant safety challenges due to their high susceptibility to lightning strikes. Therefore, the proposed hybridized composites can be used as an efficient and drapable LSP around complex shapes in AAM vehicles, offering enhanced safety and protection.
title Ar$χ$i-Textile Composites: Drapable Hybrid Woven Composites for Lightning Strike Protection
topic Applied Physics
url https://arxiv.org/abs/2511.01145