Small Structure, Large Effect: Functional Surfaces Inspired by <i>Salvinia</i> Leaves

Bing, Wei; Wang, He; Tian, Limei; Zhao, Jie; Jin, Huichao; Du, Wenbo; Ren, Luquan

doi:10.1002/sstr.202100079

Cited by 31 publications

(18 citation statements)

References 93 publications

(161 reference statements)

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“…Mimicry of the human skin represents an emerging and promising direction toward the implementation of humanoid robotics, biomimetic prosthetics, and artificial intelligence. − In the last decades, many endeavors have been dedicated to augmenting artificial skin with mechanical and thermal sensing abilities, with emphasis on the development of multifunctional materials responsive to multiple stimuli or the arranged integration of various sensory units into a hybrid system. − For example, organic semiconductors combined with a transistor , or capacitor structure were identified for a large-scale matrix of pressure and thermal sensors; carbon nanomaterials (carbon nanotubes, graphene, etc. ) with forms of yarn, , sponge, − and microstructures − were developed for flexible sensing of pressure and temperature; metal percolation or mesh was patterned into a transparent panel with pressure and temperature sensing; , ferroelectric composites with a designed interlock construction demonstrated the enhanced or self-powered sensing of pressure and temperature; − hydrogels with conductive fillers were proposed for self-healing and sensing of pressure and temperature; , and individual pressure and temperature sensory pixels connected with serpentine electrodes were applied to create a stretchable array for multifunctional sensing . Despite the thriving progress, these bimodal sensors produce signals responsive to temperature and pressure that are similar, such as relative changes in resistance, capacitance, voltage, or current.…”

Section: Introductionmentioning

confidence: 99%

Bimodal Tactile Sensor without Signal Fusion for User-Interactive Applications

Wang

Wei

et al. 2022

ACS Nano

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Tactile sensors with multimode sensing ability are cornerstones of artificial skin for applications in humanoid robotics and smart prosthetics. However, the intuitive and interference-free reading of multiple tactile signals without involving complex algorithms and calculations remains a challenge. Herein a pressure–temperature bimodal tactile sensor without any interference is demonstrated by combining the fundamentally different sensing mechanisms of optics and electronics, enabling the simultaneous and independent sensing of pressure and temperature with the elimination of signal separation algorithms and calculations. The bimodal sensor comprises a mechanoluminescent hybrid of ZnS–CaZnOS and a poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) thermoresistant material, endowing the unambiguous transduction of pressure and temperature into optical and electrical signals, respectively. This device exhibits the highest temperature sensitivity of −0.6% °C–1 in the range of 21–60 °C and visual sensing of the applied forces at a low limitation of 2 N. The interference-free and light-emitting characteristics of this device permit user-interactive applications in robotics for encrypted communication as well as temperature and pressure monitoring, along with wireless signal transmission. This work provides an unexplored solution to signal interference of multimodal tactile sensors, which can be extended to other multifunctional sensing devices.

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Section: Introductionmentioning

confidence: 99%

Bimodal Tactile Sensor without Signal Fusion for User-Interactive Applications

Wang

Wei

et al. 2022

ACS Nano

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“…Bioinspired superhydrophobic surfaces have attracted considerable attention due to their widespread applications in droplet manipulation, 1−4 oil/water separation, 5,6 friction reduction and wear resistance, 7,8 and so on. 9,10 Various methods have been developed to fabricate such surfaces, 11 such as laser processing, 12,13 etching, 14,15 three-dimensional (3D) printing, 16,17 and self-assembly. 18,19 Because of the advantages of high precision and low thermal effects, ultrafast lasers are often used to prepare such surfaces on metal, 20,21 ceramic, 22 and polymer substrates.…”

Section: Introductionmentioning

confidence: 99%

Temperature-Responsive, Femtosecond Laser-Ablated Ceramic Surfaces with Switchable Wettability for On-Demand Droplet Transfer

Zheng

Yang

Wang

et al. 2023

ACS Appl. Mater. Interfaces

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Reversible wettability transition has drawn substantial interest because of its importance for widespread applications, but facile realization of such transition on ceramic surfaces, which is promising for achieving on-demand droplet manipulation under harsh conditions, remains rare. Herein, superhydrophobic zirconia ceramic surfaces that can reversibly and repeatedly transit between superhydrophobicity and superhydrophilicity after alternate heating treatments have been fabricated using a femtosecond laser. The underlying mechanisms of the complex wettability transitions on the laser-ablated zirconia surfaces are elucidated. Hydrophilic polished zirconia surfaces immediately become superhydrophilic after laser ablation, which is mainly attributed to the amplification effect of the laser-induced micro/nanostructures and has no obvious relationship with oxygen vacancies. The obtained superhydrophilic surfaces are transformed into superhydrophobic surfaces because of rapid adsorption of airborne organic compounds driven mainly by physical interaction under heating conditions. With the alternate removal and re-adsorption of organic compounds, reversible and repeatable wettability transition between superhydrophobicity and superhydrophilicity happens on the zirconia surfaces. The laser-induced micro/nanostructures also contribute to the wettability transitions. Furthermore, utilizing the superhydrophobic zirconia surfaces with switchable wettability, on-demand transfer of strong acid droplet in air and oil droplet under strong acid solution has been achieved. This work will inspire the environmentally friendly fabrication of switchable superhydrophobic ceramic surfaces and their multifunctional applications under harsh conditions.

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“…From the view of fabrication, the fantastic combination of hierarchical structures with such heterogeneous super-hydrophobic surfaces and hydrophilic apexes makes the artificial reproduction of Salvinia -inspired microstructures a great challenge. Most of the previous studies mimicked either only the physical structure or chemical property, which limited their applications . (1) Tricinci et al fabricated hollow microstructures 100 repetitions smaller than those of natural Salvinia by direct laser lithography .…”

Section: Introductionmentioning

confidence: 99%

“…Most of the previous studies mimicked either only the physical structure or chemical property, which limited their applications. 20 (1) Tricinci et al fabricated hollow microstructures 100 repetitions smaller than those of natural Salvinia by direct laser lithography. 21 Applications in underwater hydrophobicity and localized water vapor condensation were studied.…”

Section: Introductionmentioning

confidence: 99%

Robust Underwater Air Layer Retention and Restoration on Salvinia-Inspired Self-Grown Heterogeneous Architectures

Zhang

et al. 2022

ACS Nano

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Salvinia’s long-term underwater air layer retention ability has inspired researchers to develop artificial microstructures. However, Salvinia has an exquisite combination of a complicated hollow structure and heterogeneous chemical properties, which makes artificial reproduction beyond the capabilities of traditional fabrication techniques. In addition, under extremely low underpressure conditions, the mechanism of retention and restoration of the underwater air layer of Salvinia remains unclear. Herein, by combining the shape memory polymer “top-constrained self-branching (TCSB)” and hydrophilic SiO2 microspheres trapping, four-branch hollow microstructures with heterogeneous chemical properties are fabricated. By applying underpressure, the crucial role of hydrophilic apexes is unveiled in air layer restoration. Through the calculation of the surface energy, the underlying mechanism is well interpreted. This study holds great promise for developing Salvinia-inspired artificial structures and reveals the underlying mechanism of the robust air retention and recovery capability of Salvinia leaves in extreme environments.

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Small Structure, Large Effect: Functional Surfaces Inspired by Salvinia Leaves

Cited by 31 publications

References 93 publications

Bimodal Tactile Sensor without Signal Fusion for User-Interactive Applications

Bimodal Tactile Sensor without Signal Fusion for User-Interactive Applications

Temperature-Responsive, Femtosecond Laser-Ablated Ceramic Surfaces with Switchable Wettability for On-Demand Droplet Transfer

Robust Underwater Air Layer Retention and Restoration on Salvinia-Inspired Self-Grown Heterogeneous Architectures

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