Mechanically Active Materials and Devices for Bio‐Interfaced Pressure Sensors—A Review

Nie, Zhongyi; Kwak, Jean Won; Han, Mengdi; Li, Jinghua

doi:10.1002/adma.202205609

Cited by 41 publications

(25 citation statements)

References 274 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Hysteresis is the degree of inconsistency between the loading and unloading curves, it is usually expressed as the percentage of the maximum difference between the two curves and the full scale output representing the viscoelasticity. [ 9b,24 ] We calculated the degree of hysteresis (DH) to express the hysteresis phenomenon of the LMEP:

\begin{array}{*{20}{c}}{{\rm{DH}} = \frac{{{A_{\rm{L}}} - {A_{\rm{U}}}}}{{{A_{\rm{L}}}}} \times 100\\end{array}

where A L and A U are the area of loading and unloading curves, respectively. A smaller DH value would mean lesser hysteresis of electrical signal response.…”

Section: Resultsmentioning

confidence: 99%

Segregated and Non‐Settling Liquid Metal Elastomer via Jamming of Elastomeric Particles

Xue

Zhang

et al. 2022

Adv Funct Materials

View full text Add to dashboard Cite

Liquid metal elastomer (LME)-that is, liquid metal particles dispersed in elastomer-is a soft material that has useful electric, dielectric, and thermal properties. Two issues with LME are sought to be addressed: 1) the dense liquid metal (LM) particles can settle before curing of the elastomer, and 2) the LM particles are separated by a thin layer of insulating elastomer and therefore require some "mechanical sintering" to break this layer to create conductive paths. These issues are addressed using an LME containing elastic particles (LMEP). Elastic polydimethylsiloxane particles (PPs) and LM particles jam to prevent particle settling. Meanwhile, the PPs reduce the loading necessary to create conductive paths, thus decreasing the density and cost relative to LME. Surprisingly, the particles percolate into conductive paths prior to curing the LMEP but not in LME. The dielectric constant, electrical conductivity, and thermal conductivity of LMEPs are investigated by changing the volume fraction of LM particles, polydimethylsiloxane prepolymer and PPs, and propose an LMEP with the optimal ratio. In addition, LMEP-based sensors and circuits are demonstrated for wearable electronics.

show abstract

\begin{array}{*{20}{c}}{{\rm{DH}} = \frac{{{A_{\rm{L}}} - {A_{\rm{U}}}}}{{{A_{\rm{L}}}}} \times 100\\end{array}

where A L and A U are the area of loading and unloading curves, respectively. A smaller DH value would mean lesser hysteresis of electrical signal response.…”

Section: Resultsmentioning

confidence: 99%

Segregated and Non‐Settling Liquid Metal Elastomer via Jamming of Elastomeric Particles

Xue

Zhang

et al. 2022

Adv Funct Materials

View full text Add to dashboard Cite

show abstract

“…Soft-hard composites incorporated with tissue-like materials, combined with advanced manufacturing, are one solution to this issue ( Lin et al, 2020 ). (ii) The conductivity and sensitivity of the device, the ability to self-powering or wireless powering, and methods to integrate the technologies of all components ( Nie et al, 2022 ). …”

Section: Discussionmentioning

confidence: 99%

“…(ii) The conductivity and sensitivity of the device, the ability to self-powering or wireless powering, and methods to integrate the technologies of all components ( Nie et al, 2022 ).…”

Section: Discussionmentioning

confidence: 99%

Recent advances in electronic skins: material progress and applications

Cao

Cai

2022

Front. Bioeng. Biotechnol.

View full text Add to dashboard Cite

Electronic skins are currently in huge demand for health monitoring platforms and personalized medicine applications. To ensure safe monitoring for long-term periods, high-performance electronic skins that are softly interfaced with biological tissues are required. Stretchability, self-healing behavior, and biocompatibility of the materials will ensure the future application of electronic skins in biomedical engineering. This mini-review highlights recent advances in mechanically active materials and structural designs for electronic skins, which have been used successfully in these contexts. Firstly, the structural and biomechanical characteristics of biological skins are described and compared with those of artificial electronic skins. Thereafter, a wide variety of processing techniques for stretchable materials are reviewed, including geometric engineering and acquiring intrinsic stretchability. Then, different types of self-healing materials and their applications in electronic skins are critically assessed and compared. Finally, the mini-review is concluded with a discussion on remaining challenges and future opportunities for materials and biomedical research.

show abstract

“…Moreover, due to the structural hardening and decreased compressibility of the microstructure under increasing pressure, sensitivity in the low-pressure range also tends to decrease rapidly, leading to poor linearity. 36 The graded design of microstructures enables the electrode to contact microstructures with different stiffnesses under pressure, achieving the partial unity of linearity and sensitivity in IFS. Changwoo et al recently developed a graded random wrinkled microstructure ion pressure sensor, which achieved a sensitivity of 56.91 kPa −1 under pressures ranging from 0 to 70 MPa and exhibited good linearity.…”

Section: Introductionmentioning

confidence: 99%

Normal-Direction Graded Hemispheres for Ionic Flexible Sensors with a Record-High Linearity in a Wide Working Range

Wu,

Yang,

et al. 2023

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

Flexible pressure sensors developed rapidly with increased sensitivity, a fast response time, high stability, and excellent deformability. These progresses have expanded the application of wearable electronics under high-pressure backgrounds while also bringing new challenges. In particular, the nonlinearity and narrow working range lead to a gradually insensitive response, principally because the microstructure deforms inconsistently on the device interfaces in the whole working range. Herein, we report an ionic flexible sensor with a record-high linearity (R 2 = 0.99994) in a wide working range (up to 600 kPa). The linearity response comes from the normal-direction graded hemisphere (GH) microstructure. It is prepared from poly(dimethylsiloxane) (PDMS)/carbon nanotubes (CNTs)/Au into flexible and deformable electrodes, and its geometry is precisely designed from the linear elastic theory and optimized through finite element simulation. The sensor can achieve a high sensitivity of S = 165.5 kPa–1, a response-relaxation time of <30 ms, and superb consistency, allowing the device to detect vibration signals. Our sensor has been assembled with circuits and capsulation in order to monitor the function state of players in underwater sports in the frequency domain. This work deepens the theory of linearized design of microstructures and provides a strategy to make flexible pressure sensors that have combined the performances of ultrahigh linearity, high sensitivity, and a wide working range.

show abstract

Mechanically Active Materials and Devices for Bio‐Interfaced Pressure Sensors—A Review

Cited by 41 publications

References 274 publications

Segregated and Non‐Settling Liquid Metal Elastomer via Jamming of Elastomeric Particles

Segregated and Non‐Settling Liquid Metal Elastomer via Jamming of Elastomeric Particles

Recent advances in electronic skins: material progress and applications

Normal-Direction Graded Hemispheres for Ionic Flexible Sensors with a Record-High Linearity in a Wide Working Range

Contact Info

Product

Resources

About