Superhydrophobic, carbon-infiltrated carbon nanotubes on Si and 316L stainless steel with tunable geometry

Stevens, Kimberly A.; Esplin, Christian DaLon; Davis, Taylor; Butterfield, D. Jacob; Ng, Philip S.; Bowden, Anton E.; Jensen, Brian D.; Iverson, Brian D.

doi:10.1063/1.5034471

Cited by 8 publications

(4 citation statements)

References 39 publications

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“…17 Both of these effects achieve the condition where bacteria cells have less contact area for adhesion. Because the static contact angle of CICNT is approximately 90°, 46 it is barely classified as a hydrophobic surface. 17 This suggests that most of the mechanism may be credited to the nanotubes' size and distancing.…”

Section: Discussionmentioning

confidence: 99%

Structural biofilm resistance of carbon‐infiltrated carbon nanotube coatings

Morco

Williams

Jensen

et al. 2021

Journal Orthopaedic Research

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Periprosthetic joint infection (PJI) is a devastating complication of orthopedic implant surgeries, such as total knee and hip arthroplasties. Treatment requires additional surgeries because antibiotics have limited efficacy due to biofilm formation and resistant bacterial strains such as methicillin‐resistant Staphylococcus aureus (MRSA). A non‐pharmaceutical approach is needed, and examples of this are found in nature; dragonfly and cicada wings are antibacterial because of their nanopillar surface structure rather than their chemistry. Carbon‐infiltrated carbon nanotube (CICNT) surfaces exhibit a similar nanopillar structure, and have been shown to facilitate osseointegration, and it is postulated that they might provide a structurally‐derived resistance to bacterial proliferation and biofilm formation. The objective of this study was to test the biofilm resistance of CICNT coatings. Two types of CICNT were produced: a vertically aligned CNT forest on a silicon substrate using a layer of iron as the catalyst (CICNT‐Si) and a random‐oriented CNT forest on stainless steel (SS) substrate using the substrate as the catalyst (CICNT‐SS). These were tested against SS and carbon controls. After 48 h in an MRSA biofilm reactor, samples demonstrated that both types of CICNT coatings significantly (p < 0.0001) reduced MRSA biofilm formation by 60%–80%. Morphologically, biofilm presence on both types of CICNT was also significantly reduced. Clinical Significance: Results suggest that a CICNT surface modification could be suitable and advantageous for medical devices susceptible to MRSA cell attachment and biofilm proliferation, particularly orthopedic implants.

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Section: Discussionmentioning

confidence: 99%

Structural biofilm resistance of carbon‐infiltrated carbon nanotube coatings

Morco

Williams

Jensen

et al. 2021

Journal Orthopaedic Research

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“…Stevens et al 92 grew carbon nanotubes directly on the surface of silicon or stainless steel by using the effect of carbon nanotubes infiltrating the amorphous carbon on the upper layer of multi-walled nanotubes. The material used was ethylene.…”

Section: Other Methodsmentioning

confidence: 99%

Recent advances in bioinspired superhydrophobic ice-proof surfaces: challenges and prospects

2022

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“…Thus, more approaches that are novel and simple for manufacturing hydrophobic nanocoatings on wind-turbine blades should be developed. To this end, numerous studies have been conducted to develop highly efficient hydrophobic carbon materials, including diamond [19], graphene [20], and carbon nanotubes (CNT) [21]. Eseev et al studied a simple method proposed to obtain a superhydrophobic coating made from onion-like carbon nanoparticles manufactured with a low-cost, high-tech approach [22].…”

Section: Introductionmentioning

confidence: 99%

Study on Anti-Icing Performance of Biogas-Residue Nano-Carbon Coating for Wind-Turbine Blade

Feng

Yong-xia

2023

Coatings

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Icing is a common phenomenon in nature and has a serious impact on wind turbines. Anti-icing coatings have become a major focus of industrial applications and academic research. In this study, a hydrophobic nano-carbon coating was prepared from corn-straw-biogas residue. The characterization results of the SEM, BET, FTIR, and XRD analyses showed that the hydrophobic nano-carbon has good pore structure and crystal structure. The hydrophobic and anti-icing effects of the carbon were confirmed by contact-angle measurements and anti-icing experiments. The ice thicknesses of the hydrophobic nano-carbon-coated aluminum-alloy blade (AAB) and bakelite blade (BB) were found to decrease by 1.20 mm and 1.10 mm, respectively, compared with those without coating; their weights decreased by 2.00 g and 1.31 g, respectively. The ratios of the icing areas before and after the hydrophobic nano-carbon coating of the AAB and BB were 8.15% and 9.65%, respectively. In brief, this method is a more effective technique for creating anti-icing coatings on wind-turbine blades and other outdoor apparatus.

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Superhydrophobic, carbon-infiltrated carbon nanotubes on Si and 316L stainless steel with tunable geometry

Cited by 8 publications

References 39 publications

Structural biofilm resistance of carbon‐infiltrated carbon nanotube coatings

Structural biofilm resistance of carbon‐infiltrated carbon nanotube coatings

Recent advances in bioinspired superhydrophobic ice-proof surfaces: challenges and prospects

Study on Anti-Icing Performance of Biogas-Residue Nano-Carbon Coating for Wind-Turbine Blade

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