Micropatterned Pyramidal Ionic Gels for Sensing Broad-Range Pressures with High Sensitivity

Cho, Sung Hwan; Lee, Seungwon; Yu, Seunggun; Kim, Hyeohn; Chang, Soo-Ho; Kang, Donyoung; Hwang, Ihn; Kang, Han Sol; Jeong, Beomjin; Kim, Eui Hyuk; Cho, Suk Man; Kim, Kang Lib; Lee, Hyungsuk; Shim, Wooyoung; Park, Cheolmin

doi:10.1021/acsami.7b00398

Cited by 295 publications

(249 citation statements)

References 40 publications

Supporting

Mentioning

245

Contrasting

Order By: Relevance

“…In addition, complicated circuit arrangement for multipoint recognition is regarded as a drawback to be addressed. [7,16] Compared to resistive tactile sensing mechanisms, capacitive tactile sensors have advantages in terms of temperature independence, low power consumption, stability against long-term signal drift, and easy multipoint recognition by simple assembly of row and column electrodes. [16,17] In general, the structure of a capacitive sensor consists of two parallel electrodes with a dielectric layer between them.…”

mentioning

confidence: 99%

Flexible, Transparent, Sensitive, and Crosstalk‐Free Capacitive Tactile Sensor Array Based on Graphene Electrodes and Air Dielectric

Pyo

Choi

Kim

2017

Adv Elect Materials

112

View full text Add to dashboard Cite

optical transparency, and mechanical flexibility of the sensor are considered as essential requirements for use in future tactile sensing applications. To fulfill these demands, a broad range of materials, fabrication processes, and structural designs of the tactile sensor have been developed, [8] while sensing principles are mainly classified as either resistive [9][10][11] or capacitive types. [12][13][14] Many of resistive sensors use nanomaterial-embedded composites and exploit changes in contact resistance between the nanomaterials in the composite matrix (such as elastomer) under pressure loading, showing improved pressure sensitivity and mechanical flexibility compared to silicon-or metal-based piezoresistive sensors. [15] However, resistive tactile sensors suffer from signal drift due to temperature changes and require high power consumption. In addition, complicated circuit arrangement for multipoint recognition is regarded as a drawback to be addressed. [7,16] Compared to resistive tactile sensing mechanisms, capacitive tactile sensors have advantages in terms of temperature independence, low power consumption, stability against long-term signal drift, and easy multipoint recognition by simple assembly of row and column electrodes. [16,17] In general, the structure of a capacitive sensor consists of two parallel electrodes with a dielectric layer between them. Highly compressible dielectric materials are essential to achieve high sensitivity; a lower Young's modulus of the dielectric leads to greater deformation when pressure is applied to the sensor, resulting in a larger change in capacitance. Accordingly, considerable efforts have been devoted to using elastomers with low Young's modulus as dielectric materials, including polydimethylsiloxane (PDMS), [18] polyurethane, [19] or Ecoflex. [12] However, these low-modulus elastomers also tend to have high viscoelasticity, slowing their response and relaxation times. [20] To overcome this limitation and further improve the sensitivity, a few tactile sensors make use of the strategy of structuring the dielectric layer by fabricating a microstructured surface in an orderly fashion. [7,20,21] The microstructured dielectric layer led to much higher sensitivity and faster response/relaxation time by allowing a larger deformation compared to conventional capacitive sensors with a plain dielectric layer under equal applied pressure. Nevertheless, The development of sensitive, flexible, and transparent tactile sensors is of great interest for next-generation flexible displays and human-machine interfaces. Although a few materials and structural designs have been previously developed for high-performance tactile sensors, achieving flexibility, full transparency, and highly sensitive multipoint recognition without crosstalk remains a significant challenge for such systems. This work demonstrates a capacitive tactile sensor composed of two sets of facing graphene electrodes separated by spacers, which forms an air dielectric between them. The air gap facilitates mor...

show abstract

mentioning

confidence: 99%

Flexible, Transparent, Sensitive, and Crosstalk‐Free Capacitive Tactile Sensor Array Based on Graphene Electrodes and Air Dielectric

Pyo

Choi

Kim

2017

Adv Elect Materials

112

View full text Add to dashboard Cite

show abstract

“…The screw dislocations that act as channels for transporting the ionic liquid into the QP2VP domains are apparent More importantly, the ionic liquid that is miscible with the QP2VP domains and causes them to swell plays a key role in reducing the mechanical failure during repetitive strain/release cycles when combined with the aforementioned unique confined geometry of the BCP film. Since the QP2VP domains become elastic due to the plasticization of the polymers with ionic liquid 4,38 , no large fracture of the film was observed, and the buckled structure was much finer when a BCP film with ionic liquid embedded in PDMS was stretched to 100% strain than that without ionic liquid, as shown in Fig. 4c.…”

Section: Mechanism Of the Reversible Visualization Of Strain In The Bmentioning

confidence: 99%

“…Numerous sensors have been demonstrated. The three major mechanical-to-electrical conversion principles are the capacitance [3][4][5][6][7][8] , piezo-electricity 9,10 , and piezoresistivity [11][12][13][14][15][16][17] . Piezo-based sensors rely upon either electrical voltage or resistance changes under mechanical deformation.…”

Section: Introductionmentioning

confidence: 99%

“…On the other hand, capacitive sensors utilize capacitance changes in pressure-sensitive dielectric films under mechanical stimuli. These sensors are advantageous owing to their fast response times and compact circuit layouts with vertically stacked device architectures [3][4][5][6][7] . To make these sensors suitable for various applications, particularly for largely deformable strain detection, the sensing materials should be either elastomeric or efficiently embedded in a rubbery matrix.…”

Section: Introductionmentioning

confidence: 99%

“…These requirements make the sensors tolerant to repetitive deformation [6][7][8] . Numerous previous works have been devoted to developing elastomer-based dielectrics for enhancing the sensitivity through efficient large-scale integration by combining a variety of structural architectures [3][4][5]8 . These efforts have provided data supporting the relevance of these capacitive sensors.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Block copolymer structural color strain sensor

et al. 2018

Self Cite

View full text Add to dashboard Cite

The development of electrically responsive sensors based on the capacitance, voltage, and resistance that can detect and simultaneou sly visualize the large strain involved with human motion is in great demand. Here, we demonstrate a highly stretchable, large strain capacitive sensor that can visualize strain based on the strain-responsive structural color (SC). Our device contains an elastomeric sensing film that produces a capacitance change under strain, in which a selfassembled block copolymer (BCP) photonic crystal (PC) film with 1D periodic in-plane lamellae aligned parallel to the film surface is embedded for the efficient visualization of strain. The capacitance change arises from changes in the dimensions of the elastomer film under strain. The mechanochromic BCP PC film responds to strain, giving rise to an SC change with strain. The initial red SC of the sensor blueshifts and turns blue when the sensor is stretched to 100%, resulting in a full-color SC alteration as a function of the strain. Our BCP SC strain sensor exhibits a fast strain response with multi-cycle reliability of both the capacitance and SC changes over 1000 cycles. This property allows for efficient visible recognition not only of the strained positions during finger bending and poking with a sharp object but also of the shapes of the strained objects.

show abstract

Flexible and Ultra‐Sensitive Planar Supercapacitive Pressure Sensor Based on Porous Ionic Foam

Tang

Wang

et al. 2022

Adv Eng Mater

View full text Add to dashboard Cite

Flexible pressure sensors have broad applications in the fields of electronic skin, human–computer interaction, and health monitoring. It remains a great challenge to develop advanced sensors with mechanical flexibility while gaining high sensitivity, fast response time, and wide detection range. Herein, the design and fabrication of a new type of flexible supercapacitive pressure sensor with a device configuration of planar electrodes incorporated with porous ionic gel is reported. Taking advantage of both the electric double layer capacitance and the micro‐structured organogel electrolyte, the developed sensor exhibits ultra‐high sensitivity (1126.96 kPa−1), wide detection range (300 kPa), fast response time (25 ms), and excellent stability over 6000 compression‐release cycles. With consistent and stable performance, the proposed pressure sensor can be used in many applications such as finger pressing, carotid pulse measurement, and finger bending. This work provides a facile and economical approach for fabricating flexible and ultra‐sensitive pressure sensors that are promising in wearable electronics.

show abstract

Micropatterned Pyramidal Ionic Gels for Sensing Broad-Range Pressures with High Sensitivity

Cited by 295 publications

References 40 publications

Flexible, Transparent, Sensitive, and Crosstalk‐Free Capacitive Tactile Sensor Array Based on Graphene Electrodes and Air Dielectric

Flexible, Transparent, Sensitive, and Crosstalk‐Free Capacitive Tactile Sensor Array Based on Graphene Electrodes and Air Dielectric

Block copolymer structural color strain sensor

Flexible and Ultra‐Sensitive Planar Supercapacitive Pressure Sensor Based on Porous Ionic Foam

Contact Info

Product

Resources

About