Limiting Mechanisms and Scaling of Electrostatically Controlled Adhesion of Soft Nanocomposite Surfaces for Robotic Gripping

Boutilier, Michael S. H.; Cao, Changhong; Nayakanti, Nigamaa; Kim, Sanha; Taheri-Mousavi, Seyedeh Mohadeseh; Hart, A. John

doi:10.1021/acsami.0c17096

Cited by 15 publications

(10 citation statements)

References 63 publications

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“…To characterize the tactile sensing performance, PVACNT were fixed to a sample stage and quasi-statically compressed by a flat-end indenter (whose inscribed area is larger than the lateral dimension of the entire PVACNT array) under our custom-built setup, 39 with stepper motors controlling the XYZ movement and load cells sensing the applied force (Figure 1d). The total impedance change was measured at 1 and 10 kHz using an LCR meter (Hioki IM3536) during compression with a constant loading/unloading rate of 1 μm/s.…”

Section: ■ Resultsmentioning

confidence: 99%

Low-Profile, Large-Range Compressive Strain Sensing Using Micromanufactured CNT Micropillar Arrays

Cao,

Boutilier,

Kim

et al. 2023

ACS Appl. Mater. Interfaces

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Tactile sensors, or sensors that collect measurements through touch, have versatile applications in a wide range of fields including robotic gripping, intelligent manufacturing, and biomedical technology. Hoping to match the ability of human hands to sense physical changes in objects through touch, engineers have experimented with a variety of materials from soft polymers to hard ceramics, but so far, all have fallen short. A grand challenge for developers of “human-like” bionic tactile sensors is to be able to sense a wide range of strains while maintaining the low profile necessary for compact integration. Here, we developed a low-profile tactile sensor (∼300 μm in height) based on patterned, vertically aligned carbon nanotubes (PVACNT) that can repetitively sense compressive strains of up to 75%. Upon compression, reversible changes occur in the points of contact between CNTs, producing measurable changes in electrical admittance. By patterning VACNT pillars with different aspect ratios and pitch sizes, we engineered the range and resolution of strain sensing, suggesting that CNT-based tactile sensors can be integrated according to device specifications.

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Section: ■ Resultsmentioning

confidence: 99%

Low-Profile, Large-Range Compressive Strain Sensing Using Micromanufactured CNT Micropillar Arrays

Cao,

Boutilier,

Kim

et al. 2023

ACS Appl. Mater. Interfaces

Self Cite

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“…Sanha et al introduced a soft nanocomposite of Al 2 O 3 ‐coated carbon nanotube structures to manipulate the microscale objects. [ 89 ] A meager 0.2 nm thickness of Al 2 O 3 has attained the high electrostatic attraction forces with a small voltage of 10 V. Lim et al fabricated the gripper with 1–10 wt% of Al 2 O 3 nanoparticle embedded PDMS matrix and found that 10 wt% composition attained a high force of 612 mN cm −2 which was twofold higher than the pristine PDMS gripper due to the high dielectric constant and field strength of the composite. [ 90 ] Vasudev et al utilized the barium strontium titanate interfacial layers due to its high dielectric constant which is easy to polarize by applying high potential.…”

Section: Advances In Materials and Fabrication For Ea Technologymentioning

confidence: 99%

“…[ 178 ] Recently, Michael et al fabricated the carbon nanotube covered with ultrathin aluminum oxide which makes an interesting biomimetic natural structure without complicated lithography steps. [ 89 ] The device achieved the on/off ratio of 700 with an effective distance of ≈3 μm and a maximum adhesive force of 20 kPa. Different materials adhered and the maximum adhesion was the function of dielectric break down in air which is governed by Paschen's law and the dielectric thickness as discussed in Section 2.…”

Section: Hybrid Ea Technologymentioning

confidence: 99%

Advancement of Electroadhesion Technology for Intelligent and Self‐Reliant Robotic Applications

Rajagopalan

Muthu

Liu

et al. 2022

Advanced Intelligent Systems

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The growing need for automation in industries has foreseen drastic advancements in the development of soft robotics in the areas of navigation systems, textiles, healthcare, and biometric monitoring. Electroadhesion (EA)‐based robotic applications benefit from ultralow power consumption, low maintenance, choices in versatile surfaces, sustainable life cycles, applicability in harsh and vacuum environments, and exteroceptive/proprioceptive abilities. It is of scientific and technological importance to comprehend the sequence of developments in working mechanisms, modeling, and materials to explore its full potential for future intelligent robotics systems. This review provides an all‐inclusive roadmap of EA technology from its inception to unprecedented developments and complex relationships across multidisciplines, viz., robotics, solid and fluid mechanics, electrostatics, haptics, space technologies, nanotechnology, and IoT.

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“…For example, in robotics, on‐demand bonding and debonding allow the robot arm to grip and release things. [ 8 , 9 , 10 , 11 ] Robots based on switchable adhesive can climb and stay on the wall, which attract more and more attention. [ 9 , 12 ] In smart printing systems, switchable adhesive can transfer printing small‐scale micro‐nano materials onto arbitrary substrates to fabricate integrated semiconductor devices.…”

Section: Introductionmentioning

confidence: 99%

Switchable Adhesion: On‐Demand Bonding and Debonding

Liu

Yan

2022

Advanced Science

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Adhesives have a long and illustrious history throughout human history. The development of synthetic polymers has highly improved adhesions in terms of their strength and environmental tolerance. As soft robotics, flexible electronics, and intelligent gadgets become more prevalent, adhesives with changeable adhesion capabilities will become more necessary. These adhesives should be programmable and switchable, with the ability to respond to light, electromagnetic fields, thermal, and other stimuli. These requirements necessitate novel concepts in adhesion engineering and material science. Considerable studies have been carried out to develop a wide range of adhesives. This review focuses on stimuli‐responsive material‐based adhesives, outlining current research on switchable and controlled adhesives, including design and manufacturing techniques. Finally, the potential for smart adhesives in applications, and the development of future adhesive forms are critically suggested.

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Limiting Mechanisms and Scaling of Electrostatically Controlled Adhesion of Soft Nanocomposite Surfaces for Robotic Gripping

Cited by 15 publications

References 63 publications

Low-Profile, Large-Range Compressive Strain Sensing Using Micromanufactured CNT Micropillar Arrays

Low-Profile, Large-Range Compressive Strain Sensing Using Micromanufactured CNT Micropillar Arrays

Advancement of Electroadhesion Technology for Intelligent and Self‐Reliant Robotic Applications

Switchable Adhesion: On‐Demand Bonding and Debonding

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