Stretchable, Twisted Conductive Microtubules for Wearable Computing, Robotics, Electronics, and Healthcare

Nho, Thanh; Visell, Yon

doi:10.1038/s41598-017-01898-8

Cited by 77 publications

(53 citation statements)

References 38 publications

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“…[43] Experiments were conducted for 100 cycles of twist-untwist events (this experiment is provided in Video S1, Supporting Information). Such tests simulate torsion, one of the most common stresses experienced by a flexible material.…”

Section: Resultsmentioning

confidence: 99%

Sustainable Electronics Based on Crop Plant Extracts and Graphene: A “Bioadvantaged” Approach

Cataldi

Heredia‐Guerrero

Guzmán-Puyol

et al. 2018

Advanced Sustainable Systems

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In today's fast‐paced and well‐connected world, consumer electronics are evolving rapidly. As a result, the amount of discarded electronic devices is becoming a major health and environmental concern. The rapid expansion of flexible electronics has the potential to transform consumer electronic devices from rigid phones and tablets to robust wearable devices. This means increased use of plastics in consumer electronics and the potential to generate more persistent plastic waste for the environment. Hence, today, the need for flexible biodegradable electronics is at the forefront of minimizing the mounting pile of global electronic waste. A “bioadvantaged” approach to develop a biodegradable, flexible, and application‐adaptable electronic components based on crop components and graphene is reported. More specifically, by combining zein, a corn‐derived protein, and aleuritic acid, a major monomer of tomato cuticles and sheellac, along with graphene, biocomposite conductors having low electrical resistance (≈10 Ω sq−1) with exceptional mechanical and fatigue resilience are fabricated. Further, a number of high‐performance electronic applications, such as THz electromagnetic shielding, flexible GHz antenna construction, and flexible solar cell electrode, are demonstrated. Excellent performance results are measured from each application comparable to conventional nondegrading counterparts, thus paving the way for the concept of “plant‐e‐tronics” towards sustainability.

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Section: Resultsmentioning

confidence: 99%

Sustainable Electronics Based on Crop Plant Extracts and Graphene: A “Bioadvantaged” Approach

Cataldi

Heredia‐Guerrero

Guzmán-Puyol

et al. 2018

Advanced Sustainable Systems

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“…They can flexibly adapt to a great variety of configurations, and to different mechanical settings, can ensure safe cooperation with humans, and can facilitate the coordination of large numbers of degrees of freedom . Many types of stretchable and wearable sensors, soft actuators, soft energy harvesters, and storage devices have been developed, often motivated by applications in robotics, healthcare, and other domains. Mechanical systems based on soft actuators are also adaptable to systems of greatly varying length scales, ranging from miniature grippers, to mobile robots, wearable tactile displays, and biomedical devices .…”

Section: Introductionmentioning

confidence: 99%

“…These materials have excellent electrical conductivity (EGaIn, σ = 3.4 × 10 4 S cm −1 ) and thermal conductivity (EGaIn, κ e = 24.9 W m −1 K −1 ), low melting point (EGaIn, 15.7 °C), low vapor pressure, and low toxicity . When introduced into channels of a soft substrate, such as a polymer elastomer, they can facilitate a wide range of applications from soft wearable sensors, to soft electronic interconnects, stretchable RF antennas, and soft liquid metal actuators …”

Section: Introductionmentioning

confidence: 99%

Miniature Soft Electromagnetic Actuators for Robotic Applications

Nho

Phan

Nguyen

et al. 2018

Adv Funct Materials

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147

123

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Electromagnetic actuators (EMAs) serve the majority of motion control needs in fields ranging from industrial robotics to automotive systems and biomedical devices, due to their unmatched combination of speed, precision, force, and scalability. This paper describes the design and fabrication of miniature soft EMAs that operate based on the Lorentz force principle. The actuators are fabricated from silicone polymer, liquid metal (LM) alloy (eutectic gallium indium, EGaIn), and magnetic (NdFeB) powder. They are small, intrinsically deformable, and can be fabricated using simple techniques. The central elements of the actuators are fine, 3D helical coil conductors, which are used as electromagnetic inductors. The coils are formed from stretchable filaments that are filled with a LM alloy. To achieve high power densities, the filaments themselves may be fabricated from colloids of EGaIn microdroplets in a silicone polymer matrix, allowing them to dissipate heat and accommodate high currents, and thus high forces. Millimeter-scale cylindrical actuators are demonstrated for linear high frequency motion and articulated devices for bending motion. These actuators are applied in a vibrotactile feedback display and in a miniature soft robotic gripper.

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“…Flexible electronics have captured tremendous attention in recent years due to their potential applications in wearable devices, implanted systems, and brain–machine interfaces, and it is often desired that they possess multiple functionalities, tunable properties, low‐power consumption, as well as mechanical reliability and performance robustness, even under demanding environment. One particular system of extensive interests is flexible ferroelectric field effect transistors (FeFETs), which are capable of both low power sensing and nonvolatile data storage that are attractive for smart wearable devices, and the ability to continuously tune and program their multiple conduction states makes them promising for emerging memristor applications as well, e.g., as artificial synapses in neuromorphic computing .…”

Section: Introductionmentioning

confidence: 99%

Highly Robust Flexible Ferroelectric Field Effect Transistors Operable at High Temperature with Low‐Power Consumption

Ren

Zhong

Xiao

et al. 2019

Adv Funct Materials

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Flexible ferroelectric field effect transistors (FeFETs) with multiple functionalities and tunable properties are attractive for low power sensing, nonvolatile data storage, as well as emerging memristor applications such as artificial synapses, though the state-of-art flexible FeFETs based on organic materials possess low polarization, large coercivity, and high operating voltage, and suffer from poor thermal stability. Here, developed is an all-inorganic flexible FeFET based on epitaxial Pb(Zr 0.1 Ti 0.9 )O 3 /ZnO heterostructure on a mica substrate, which not only operates under a small voltage (±6 V) and thus consumes low power with an excellent on/off ratio of 10 4 as well as retention characteristics, but also shows robust FeFET performance under large bending deformation (4 mm), extended bending cycling (500 cycles), and high temperature operation at 200 °C. Importantly, the FeFET characteristics depend on temperature, but not on temperature history, critical for operation under repeated thermal loading. The excellent mechanical flexibility and functional robustness of the flexible FeFET originate from the unique van der Waals bonded layer structure of mica, facilitating a small bending radius yet modest strain. This work demonstrates the great promise of mica as a universal platform to integrate complicated functional devices for flexible electronics, especially under harsh environment.

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Stretchable, Twisted Conductive Microtubules for Wearable Computing, Robotics, Electronics, and Healthcare

Cited by 77 publications

References 38 publications

Sustainable Electronics Based on Crop Plant Extracts and Graphene: A “Bioadvantaged” Approach

Sustainable Electronics Based on Crop Plant Extracts and Graphene: A “Bioadvantaged” Approach

Miniature Soft Electromagnetic Actuators for Robotic Applications

Highly Robust Flexible Ferroelectric Field Effect Transistors Operable at High Temperature with Low‐Power Consumption

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