Superhydrophobic SERS substrates based on silicon hierarchical nanostructures

Chen, Xuexian; Wen, Jinxiu; Zhou, Jianhua; Zheng, Zebo; An, Di; Wang, Hao; Xie, Weiguang; Zhan, Runze; Xu, Ning; Chen, Jun; She, Juncong; Chen, Huanjun; Deng, Shaozhi

doi:10.1088/2040-8986/aaa100

Cited by 13 publications

(6 citation statements)

References 37 publications

(39 reference statements)

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“…The signal intensities of characteristic bands at 1179 cm −1 (orange) and 1363 cm −1 (green) were, respectively, linear with the logarithm of CV concentrations. Therefore, the quantitative detection limit of the CRESHbased SERS platform was at least 3 orders of magnitude better than that of SH surfaces with previous static evaporation, 31,41 while comparable to that of state-of-the-art slippery surfaces. 24 To evaluate the spot-to-spot uniformity of the aggregate nanostructure fabricated based on CRESH, multiple Raman measurements were performed on the same CV/AuNP aggregate.…”

Section: ■ Results and Discussionmentioning

confidence: 77%

Surface-Enhanced Raman Scattering Trace-Detection Platform Based on Continuous-Rolling-Assisted Evaporation on Superhydrophobic Surfaces

Sun

Chen

Zheng

et al. 2020

ACS Appl. Nano Mater.

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Surface-enhanced Raman scattering (SERS) has proved to be an efficient approach for ultrasensitive detection of highly diluted analytes, and the metal colloid-based SERS platform is one of the most successful techniques to perform evaporationassisted collection and enrichment of highly diluted molecules in hot spot regions on various substrates. However, there are still no effective and facile ways to achieve high SERS sensitivity at femtomolar levels on superhydrophobic (SH) surfaces. Here, for the first time, an efficient and versatile strategy, termed continuousrolling-assisted evaporation on an SH surface (CRESH), is developed for the ultrasensitive colloid-based SERS platform, which overcomes the inherent limitations of the pinning effect during evaporative enrichment on unpatterned SH substrates. This strategy combines an SH surface with a rolling property and droplet continuous-rolling motion in a synergistic way to achieve trace analyte detection at the femtomolar level. A 50 μL droplet based on CRESH can be considerably condensed from approximately 0.6 cm to 0.2 mm in diameter, and final sizes are independent of the initial droplet volumes, showing remarkable condensing efficiency and potential applications for a lower detection limit. Our results of numerical analysis of nanoparticle motions inside the droplet show, in contrast to common belief, that the CRESH strategy endows the SH surface with nearly pinning-free peculiarity by means of significantly reducing the critical contact line values when the Cassie−Wenzel transition occurs. As a proof of concept, CRESH is further evaluated by detecting trace quantities of Raman probes with quantitative SERS detection down to the femtomolar level (1 × 10 −15 mol/L). Our platform may open the possibility of universal applications of unpatterned SH surfaces that have long been suspected to play a role in effective, facile, cost-effective, and ultrasensitive SERS detection.

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Section: ■ Results and Discussionmentioning

confidence: 77%

Surface-Enhanced Raman Scattering Trace-Detection Platform Based on Continuous-Rolling-Assisted Evaporation on Superhydrophobic Surfaces

Sun

Chen

Zheng

et al. 2020

ACS Appl. Nano Mater.

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“…Inspired by Nature, scientists have designed superhydrophobic surfaces for many crucial applications such as anti-icing ( Onda et al, 1996 ; Lin et al, 2011 ; Latthe et al, 2019 ), biosensing ( Xu et al, 2017 ; He et al, 2018 ; Song et al, 2018 ; Xu et al, 2018 ; Xu et al, 2019 ), energy storage ( Sun et al, 2019 ), and surface-enhanced Raman scattering (SERS) ( Chen et al, 2018 ). The hierarchically structured surface was found to be one of the key factors for the superhydrophobic property because it provides a composite surface consisting of both solid surfaces as well as air pockets, thereby increasing the contact angle and rendering more repellent surfaces for water ( Feng et al, 2002 ; Liu et al, 2020b ; Wu et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Bio-Inspired Hierarchical Micro/Nanostructured Surfaces for Superhydrophobic and Anti-Ice Applications

Zhang

Uzoma

Xiaoyang

et al. 2022

Front. Bioeng. Biotechnol.

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We report a scalable and cost-effective fabrication approach for constructing bio-inspired micro/nanostructured surfaces. It involves silicon microstructure etching using a deep reactive ion etch (DRIE) method, nanowires deposition via glancing angle deposition (GLAD) process, and fluorocarbon thin film deposition. Compared with the smooth, microstructured, and nanostructured surfaces, the hierarchical micro/nanostructured surfaces obtained via this method showed the highest water contact angle of ∼161° and a low sliding angle of <10°. It also offered long ice delay times of 2313 s and 1658 s at −5°C and −10°C respectively, more than 10 times longer than smooth surfaces indicating excellent anti-icing properties and offering promising applications in low-temperature environments. These analyses further proved that the surface structures have a significant influence on surface wettability and anti-icing behavior. Hence, the GLAD process which is versatile and cost-effective offers the freedom of constructing nanostructures on top of microstructures to achieve the required objective in the fabrication of micro/nanostructured surfaces when compared to other fabrication techniques.

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“…9,10 This increased roughness provides the basis for Cassie−Baxter or Wenzel wetting states. 11,12 Conventional techniques to accomplish roughness include etching, 13−15 electrochemical deposition, 16,17 templating, 18,19 spray coatings, 20,21 sputtering followed by thermal annealing, 22 spin coating, 23 and sol−gel processes. 24 To closely replicate the lotus effect, researchers commonly employ a series of manufacturing steps to introduce a hierarchy of structures ranging from the nanometer to hundreds of micrometer lengthscales.…”

Section: ■ Introductionmentioning

confidence: 99%

“…To develop repellent materials, researchers aim to create superhydrophobic surfaces characterized by contact angles >150 degrees and sliding angles <10° . Strategies such as physical modifications to add roughness inspired by the multiscale texture found on lotus leaves and butterfly wings are commonly used to create repellent surfaces. , This increased roughness provides the basis for Cassie–Baxter or Wenzel wetting states. , Conventional techniques to accomplish roughness include etching, − electrochemical deposition, , templating, , spray coatings, , sputtering followed by thermal annealing, spin coating, and sol–gel processes . To closely replicate the lotus effect, researchers commonly employ a series of manufacturing steps to introduce a hierarchy of structures ranging from the nanometer to hundreds of micrometer lengthscales. − By implementing multiple-step approaches, both micro- and nanoscale features are established on surfaces, which can be employed for biorepellency. ,, While these techniques have demonstrated high performance in terms of superhydrophobicity and pathogen repellency, it is often difficult to produce these surfaces on a large scale due to the complexities of the multistep manufacturing methods and the prohibitive costs of the reagents and processes involved …”

Section: Introductionmentioning

confidence: 99%

Producing Fluorine- and Lubricant-Free Flexible Pathogen- and Blood-Repellent Surfaces Using Polysiloxane-Based Hierarchical Structures

Ladouceur

Shakeri

Khan

et al. 2022

ACS Appl. Mater. Interfaces

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High-touch surfaces are known to be a major route for the spread of pathogens in healthcare and public settings. Antimicrobial coatings have, therefore, garnered significant attention to help mitigate the transmission of infectious diseases via the surface route. Among antimicrobial coatings, pathogen-repellent surfaces provide unique advantages in terms of safety in public settings such as instant repellency, affordability, biocompatibility, and long-term stability. While there have been many advances in the fabrication of biorepellent surfaces in the past two decades, this area of research continues to suffer challenges in scalability, cost, compatibility with high-touch applications, and performance for pathogen repellency. These features are critical for high-touch surfaces to be used in public settings. Additionally, the environmental impact of manufacturing repellent surfaces remains a challenge, mainly due to the use of fluorinated coatings. Here, we present a flexible hierarchical coating with straightforward and cost-effective manufacturing without the use of fluorine or a lubricant. Hierarchical surfaces were prepared through the growth of polysiloxane nanostructures using n-propyltrichlorosilane (n-PTCS) on activated polyolefin (PO), followed by heat shrinking to induce microscale wrinkles. The developed coatings demonstrated repellency, with contact angles over 153°and sliding angles <1°. In assays mimicking touch, these hierarchical surfaces demonstrated a 97.5% reduction in transmission of Escherichia coli (E.coli), demonstrating their potential as antimicrobial coatings to mitigate the spread of infectious diseases. Additionally, the developed surfaces displayed a 93% reduction in blood staining after incubation with human whole blood, confirming repellent properties that reduce bacterial deposition.

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Superhydrophobic SERS substrates based on silicon hierarchical nanostructures

Cited by 13 publications

References 37 publications

Surface-Enhanced Raman Scattering Trace-Detection Platform Based on Continuous-Rolling-Assisted Evaporation on Superhydrophobic Surfaces

Surface-Enhanced Raman Scattering Trace-Detection Platform Based on Continuous-Rolling-Assisted Evaporation on Superhydrophobic Surfaces

Bio-Inspired Hierarchical Micro/Nanostructured Surfaces for Superhydrophobic and Anti-Ice Applications

Producing Fluorine- and Lubricant-Free Flexible Pathogen- and Blood-Repellent Surfaces Using Polysiloxane-Based Hierarchical Structures

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