Embedment of sensing elements for robust, highly sensitive, and cross-talk–free iontronic skins for robotics applications

Junli Shi; Yuan Dai; Yu Cheng; Sai Xie; Gang Li; Yuan Liu; Jingxiao Wang; Ruirui Zhang; Ningning Bai; Minkun Cai; Yuan Zhang; Yifei Zhan; Zhengyou Zhang; Cunjiang Yu; Chuan Fei Guo

doi:10.1126/sciadv.adf8831

Embedment of sensing elements for robust, highly sensitive, and cross-talk–free iontronic skins for robotics applications

Junli Shi, Yuan Dai, Yu Cheng, Sai Xie, Gang Li, Yuan Liu, Jingxiao Wang, Ruirui Zhang, Ningning Bai, Minkun Cai, Yuan Zhang, Yifei Zhan, Zhengyou Zhang, Cunjiang Yu, Chuan Fei Guo

Research output: Contribution to journal › Article › peer-review

Abstract

Iontronic pressure sensors are promising in robot haptics because they can achieve high sensing performance using nanoscale electric double layers (EDLs) for capacitive signal output. However, it is challenging to achieve both high sensitivity and high mechanical stability in these devices. Iontronic sensors need microstructures that offer subtly changeable EDL interfaces to boost sensitivity, while the microstructured interfaces are mechanically weak. Here, we embed isolated microstructured ionic gel (IMIG) in a hole array (28 × 28) of elastomeric matrix and cross-link the IMIGs laterally to achieve enhanced interfacial robustness without sacrificing sensitivity. The embedded configuration toughens and strengthens the skin by pinning cracks and by the elastic dissipation of the interhole structures. Furthermore, cross-talk between the sensing elements is suppressed by isolating the ionic materials and by designing a circuit with a compensation algorithm. We have demonstrated that the skin is potentially useful for robotic manipulation tasks and object recognition.

Original language	English (US)
Article number	eadf8831
Journal	Science Advances
Volume	9
Issue number	9
DOIs	https://doi.org/10.1126/sciadv.adf8831
State	Published - Mar 3 2023
Externally published	Yes

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10.1126/sciadv.adf8831

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@article{475da0a0717a4213b5aac47306cdcde9,

title = "Embedment of sensing elements for robust, highly sensitive, and cross-talk–free iontronic skins for robotics applications",

abstract = "Iontronic pressure sensors are promising in robot haptics because they can achieve high sensing performance using nanoscale electric double layers (EDLs) for capacitive signal output. However, it is challenging to achieve both high sensitivity and high mechanical stability in these devices. Iontronic sensors need microstructures that offer subtly changeable EDL interfaces to boost sensitivity, while the microstructured interfaces are mechanically weak. Here, we embed isolated microstructured ionic gel (IMIG) in a hole array (28 × 28) of elastomeric matrix and cross-link the IMIGs laterally to achieve enhanced interfacial robustness without sacrificing sensitivity. The embedded configuration toughens and strengthens the skin by pinning cracks and by the elastic dissipation of the interhole structures. Furthermore, cross-talk between the sensing elements is suppressed by isolating the ionic materials and by designing a circuit with a compensation algorithm. We have demonstrated that the skin is potentially useful for robotic manipulation tasks and object recognition.",

author = "Junli Shi and Yuan Dai and Yu Cheng and Sai Xie and Gang Li and Yuan Liu and Jingxiao Wang and Ruirui Zhang and Ningning Bai and Minkun Cai and Yuan Zhang and Yifei Zhan and Zhengyou Zhang and Cunjiang Yu and Guo, {Chuan Fei}",

note = "Acknowledgments Funding:TheworkconductedatSUST ech wasfundedbytheNationalNaturalScience FoundationofChina(nos.T2225017and52073138),theGuangdongInnova tiv eand EntrepreneurialResearchT eam Program(no.2016ZT06G587),theScienceT echnology and InnovationCommitteeofShenzhenMunicipality(no.JCYJ20210324120202007),theShenzhen Sci-T ech Fund(no.YTDPT20181011104007),theT encent RoboticsXLabRhino-BirdFocused ResearchProgram(T encent JR2021TEG001),andtheGuangdongProvincialKeyLaboratory Program(no.2021B1212040001).Authorcontributions:C.F .G. andJ.S.conceivedtheideaand designed the research. J.S. performed most of the experiments. Y .D. designed the signal acquisitionsystemandR.Z.preparedthecircuit.J.S.,S.X.,andN.B.analyzedthesensing properties.G.L.andJ.W .analyzedtheinterfacialperformance.M.C.performedSEMobservation. Y .Z. analyzedtheperformanceofelectrodes.J.S.performedtheisolatedionicgelfabrication. Y .C. and Y .F .Z. performed object recognition by machine learning. C.F .G., J.S., and Y .D. drafted themanuscript,andallauthorscontributedtothewritingofthemanuscript.Competing interests:Theauthorsdeclarethattheyhav enocompetinginterest.Dataandmaterials availability:Alldataneededtoevaluatetheconclusionsinthepaperarepresentinthepaper and/ortheSupplementaryMaterials.",

year = "2023",

month = mar,

day = "3",

doi = "10.1126/sciadv.adf8831",

language = "English (US)",

volume = "9",

journal = "Science Advances",

issn = "2375-2548",

publisher = "American Association for the Advancement of Science",

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TY - JOUR

T1 - Embedment of sensing elements for robust, highly sensitive, and cross-talk–free iontronic skins for robotics applications

AU - Shi, Junli

AU - Dai, Yuan

AU - Cheng, Yu

AU - Xie, Sai

AU - Li, Gang

AU - Liu, Yuan

AU - Wang, Jingxiao

AU - Zhang, Ruirui

AU - Bai, Ningning

AU - Cai, Minkun

AU - Zhang, Yuan

AU - Zhan, Yifei

AU - Zhang, Zhengyou

AU - Yu, Cunjiang

AU - Guo, Chuan Fei

N1 - Acknowledgments Funding:TheworkconductedatSUST ech wasfundedbytheNationalNaturalScience FoundationofChina(nos.T2225017and52073138),theGuangdongInnova tiv eand EntrepreneurialResearchT eam Program(no.2016ZT06G587),theScienceT echnology and InnovationCommitteeofShenzhenMunicipality(no.JCYJ20210324120202007),theShenzhen Sci-T ech Fund(no.YTDPT20181011104007),theT encent RoboticsXLabRhino-BirdFocused ResearchProgram(T encent JR2021TEG001),andtheGuangdongProvincialKeyLaboratory Program(no.2021B1212040001).Authorcontributions:C.F .G. andJ.S.conceivedtheideaand designed the research. J.S. performed most of the experiments. Y .D. designed the signal acquisitionsystemandR.Z.preparedthecircuit.J.S.,S.X.,andN.B.analyzedthesensing properties.G.L.andJ.W .analyzedtheinterfacialperformance.M.C.performedSEMobservation. Y .Z. analyzedtheperformanceofelectrodes.J.S.performedtheisolatedionicgelfabrication. Y .C. and Y .F .Z. performed object recognition by machine learning. C.F .G., J.S., and Y .D. drafted themanuscript,andallauthorscontributedtothewritingofthemanuscript.Competing interests:Theauthorsdeclarethattheyhav enocompetinginterest.Dataandmaterials availability:Alldataneededtoevaluatetheconclusionsinthepaperarepresentinthepaper and/ortheSupplementaryMaterials.

PY - 2023/3/3

Y1 - 2023/3/3

N2 - Iontronic pressure sensors are promising in robot haptics because they can achieve high sensing performance using nanoscale electric double layers (EDLs) for capacitive signal output. However, it is challenging to achieve both high sensitivity and high mechanical stability in these devices. Iontronic sensors need microstructures that offer subtly changeable EDL interfaces to boost sensitivity, while the microstructured interfaces are mechanically weak. Here, we embed isolated microstructured ionic gel (IMIG) in a hole array (28 × 28) of elastomeric matrix and cross-link the IMIGs laterally to achieve enhanced interfacial robustness without sacrificing sensitivity. The embedded configuration toughens and strengthens the skin by pinning cracks and by the elastic dissipation of the interhole structures. Furthermore, cross-talk between the sensing elements is suppressed by isolating the ionic materials and by designing a circuit with a compensation algorithm. We have demonstrated that the skin is potentially useful for robotic manipulation tasks and object recognition.

AB - Iontronic pressure sensors are promising in robot haptics because they can achieve high sensing performance using nanoscale electric double layers (EDLs) for capacitive signal output. However, it is challenging to achieve both high sensitivity and high mechanical stability in these devices. Iontronic sensors need microstructures that offer subtly changeable EDL interfaces to boost sensitivity, while the microstructured interfaces are mechanically weak. Here, we embed isolated microstructured ionic gel (IMIG) in a hole array (28 × 28) of elastomeric matrix and cross-link the IMIGs laterally to achieve enhanced interfacial robustness without sacrificing sensitivity. The embedded configuration toughens and strengthens the skin by pinning cracks and by the elastic dissipation of the interhole structures. Furthermore, cross-talk between the sensing elements is suppressed by isolating the ionic materials and by designing a circuit with a compensation algorithm. We have demonstrated that the skin is potentially useful for robotic manipulation tasks and object recognition.

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DO - 10.1126/sciadv.adf8831

M3 - Article

C2 - 36867698

AN - SCOPUS:85149443787

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VL - 9

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JF - Science Advances

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ER -

Embedment of sensing elements for robust, highly sensitive, and cross-talk–free iontronic skins for robotics applications

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