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    Journals >Nano-Micro Letters >Volume 16 >Issue 1 >Page 267 > Article
    • Nano-Micro Letters
    • Vol. 16, Issue 1, 267 (2024)
    Blade-Coated Porous 3D Carbon Composite Electrodes Coupled with Multiscale Interfaces for Highly Sensitive All-Paper Pressure Sensors
    Bowen Zheng1, Ruisheng Guo1,*, Xiaoqiang Dou1, Yueqing Fu1..., Bingjun Yang2,**, Xuqing Liu1,4,*** and Feng Zhou3,4|Show fewer author(s)
    Author Affiliations
  • 1State Key Laboratory of Solidification Processing, Center of Advanced Lubrication and Seal Materials, School of Materials Science and Engineering, Northwestern Polytechnical University, Xi’an 710072, People’s Republic of China
  • 2Research Center of Resource Chemistry and Energy Materials, State Key Laboratory of Solid Lubrication, Lanzhou Institute of Chemical Physics, Chinese of Academy of Sciences, Lanzhou 730000, People’s Republic of China
  • 3State Key Laboratory of Solid Lubrication, Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences, Lanzhou 730000, People’s Republic of China
  • 4Shandong Laboratory of Advanced Materials and Green Manufacturing at Yantai, Yantai, 264006, People’s Republic of China
    • show less
    DOI: 10.1007/s40820-024-01488-0 Cite this Article
    Bowen Zheng, Ruisheng Guo, Xiaoqiang Dou, Yueqing Fu, Bingjun Yang, Xuqing Liu, Feng Zhou. Blade-Coated Porous 3D Carbon Composite Electrodes Coupled with Multiscale Interfaces for Highly Sensitive All-Paper Pressure Sensors[J]. Nano-Micro Letters, 2024, 16(1): 267 Copy Citation Text show less
    References

    [1] Q.-J. Sun, X.-H. Zhao, Y. Zhou, C.-C. Yeung, W. Wu et al., Fingertip-skin-inspired highly sensitive and multifunctional sensor with hierarchically structured conductive graphite/polydimethylsiloxane foams. Adv. Funct. Mater. 29, 1808829 (2019).

    [2] L. Chen, M. Lu, H. Yang, J.R. Salas Avila, B. Shi et al., Textile-based capacitive sensor for physical rehabilitation via surface topological modification. ACS Nano 14, 8191–8201 (2020).

    [3] L. Shi, Z. Li, M. Chen, Y. Qin, Y. Jiang et al., Quantum effect-based flexible and transparent pressure sensors with ultrahigh sensitivity and sensing density. Nat. Commun. 11, 3529 (2020).

    [4] S. Baek, Y. Lee, J. Baek, J. Kwon, S. Kim et al., Spatiotemporal measurement of arterial pulse waves enabled by wearable active-matrix pressure sensor arrays. ACS Nano 16, 368–377 (2022).

    [5] Z. Shi, L. Meng, X. Shi, H. Li, J. Zhang et al., Morphological engineering of sensing materials for flexible pressure sensors and artificial intelligence applications. Nano-Micro Lett. 14, 141 (2022).

    [6] R. Kaveti, J.H. Lee, J.K. Youn, T.-M. Jang, W.B. Han et al., Soft, long-lived, bioresorbable electronic surgical mesh with wireless pressure monitor and on-demand drug delivery. Adv. Mater. 36, 2307391 (2024).

    [7] R. Chen, T. Luo, J. Wang, R. Wang, C. Zhang et al., Nonlinearity synergy: an elegant strategy for realizing high-sensitivity and wide-linear-range pressure sensing. Nat. Commun. 14, 6641 (2023).

    [8] H. Wang, X. Dou, Z. Wang, Z. Liu, Q. Ye et al., Boosting sensitivity and durability of pressure sensors based on compressible Cu sponges by strengthening adhesion of “rigid-soft” interfaces. Small 19, 2303234 (2023).

    [9] K. Pang, X. Song, Z. Xu, X. Liu, Y. Liu et al., Hydroplastic foaming of graphene aerogels and artificially intelligent tactile sensors. Sci. Adv. 6, 4045 (2020).

    [10] B. Yin, X. Liu, H. Gao, T. Fu, J. Yao, Bioinspired and bristled microparticles for ultrasensitive pressure and strain sensors. Nat. Commun. 9, 5161 (2018).

    [11] S. Yu, L. Li, J. Wang, E. Liu, J. Zhao et al., Light-boosting highly sensitive pressure sensors based on bioinspired multiscale surface structures. Adv. Funct. Mater. 30, 1907091 (2020).

    [12] Y. Lee, J. Park, S. Cho, Y.-E. Shin, H. Lee et al., Flexible ferroelectric sensors with ultrahigh pressure sensitivity and linear response over exceptionally broad pressure range. ACS Nano 12, 4045–4054 (2018).

    [13] M. Ha, S. Lim, J. Park, D.-S. Um, Y. Lee et al., Bioinspired interlocked and hierarchical design of ZnO nanowire arrays for static and dynamic pressure-sensitive electronic skins. Adv. Funct. Mater. 25, 2841–2849 (2015).

    [14] Y. Zhang, T.-H. Chang, L. Jing, K. Li, H. Yang et al., Heterogeneous, 3D architecturing of 2D titanium carbide (MXene) for microdroplet manipulation and voice recognition. ACS Appl. Mater. Interfaces 12, 8392–8402 (2020).

    [15] W. Lin, C. Wei, S. Yu, Z. Chen, C. Zhang et al., Programmable and ultrasensitive haptic interfaces enabling closed-loop human–machine interactions. Adv. Funct. Mater. 33, 2305919 (2023).

    [16] Y. Xu, Q. Fei, M. Page, G. Zhao, Y. Ling et al., Paper-based wearable electronics. iScience 24, 102736 (2021).

    [17] Y. Zhang, T. Zhang, Z. Huang, J. Yang, A new class of electronic devices based on flexible porous substrates. Adv. Sci. 9, e2105084 (2022).

    [18] Z. Liu, T. Zhu, J. Wang, Z. Zheng, Y. Li et al., Functionalized fiber-based strain sensors: pathway to next-generation wearable electronics. Nano-Micro Lett. 14, 61 (2022).

    [19] L. Yang, H. Wang, W. Yuan, Y. Li, P. Gao et al., Wearable pressure sensors based on MXene/tissue papers for wireless human health monitoring. ACS Appl. Mater. Interfaces 13, 60531–60543 (2021).

    [20] D. Wang, D. Zhang, P. Li, Z. Yang, Q. Mi et al., Electrospinning of flexible Poly(vinyl alcohol)/MXene nanofiber-based humidity sensor self-powered by monolayer molybdenum diselenide piezoelectric nanogenerator. Nano-Micro Lett. 13, 57 (2021).

    [21] T. Xu, Q. Song, K. Liu, H. Liu, J. Pan et al., Nanocellulose-assisted construction of multifunctional MXene-based aerogels with engineering biomimetic texture for pressure sensor and compressible electrode. Nano-Micro Lett. 15, 98 (2023).

    [22] Z. Wang, J. Ding, R. Guo, Printable all-paper pressure sensors with high sensitivity and wide sensing range. ACS Appl. Mater. Interfaces 15, 4789–4798 (2023).

    [23] S.Y. An, B.T. McAllister, E. Grignon, S. Evariste, D.S. Seferos, Increasing ionic conductivity in polymer electrodes using oxanorbornene. EcoMat 4, e12178 (2022).

    [24] L.-Q. Tao, K.-N. Zhang, H. Tian, Y. Liu, D.-Y. Wang et al., Graphene-paper pressure sensor for detecting human motions. ACS Nano 11, 8790–8795 (2017).

    [25] Z. Ren, H. Zhang, N. Liu, D. Lei, Q. Zhang et al., Self-powered 2D nanofluidic graphene pressure sensor with Serosa-Mimetic structure. EcoMat 5, e12299 (2023).

    [26] S. Chen, Y. Wang, L. Yang, F. Karouta, K. Sun, Electron-induced perpendicular graphene sheets embedded porous carbon film for flexible touch sensors. Nano-Micro Lett. 12, 136 (2020).

    [27] R. Matsukawa, D. Kobayashi, H. Mitsui, T. Ikuno, Environment-friendly paper-based flexible pressure sensors with carbon nanotubes and liquid metal. Appl. Phys. Express 13, 027001 (2020).

    [28] X. Sun, J. Sun, T. Li, S. Zheng, C. Wang et al., Flexible tactile electronic skin sensor with 3D force detection based on porous CNTs/PDMS nanocomposites. Nano-Micro Lett. 11, 57 (2019).

    [29] B. Liang, Z. Zhang, W. Chen, D. Lu, L. Yang et al., Direct patterning of carbon nanotube via stamp contact printing process for stretchable and sensitive sensing devices. Nano-Micro Lett. 11, 92 (2019).

    [30] L. Gao, C. Zhu, L. Li, C. Zhang, J. Liu et al., All paper-based flexible and wearable piezoresistive pressure sensor. ACS Appl. Mater. Interfaces 11, 25034–25042 (2019).

    [31] C. Wang, K. Xia, H. Wang, X. Liang, Z. Yin et al., Advanced carbon for flexible and wearable electronics. Adv. Mater. 31, 1801072 (2019).

    [32] Z. Li, F. Chen, N. Zhu, L. Zhang, Z. Xie, Tip-enhanced sub-femtomolar steroid immunosensing via micropyramidal flexible conducting polymer electrodes for at-home monitoring of salivary sex hormones. ACS Nano 17, 21935–21946 (2023).

    [33] I. Muguet, A. Maziz, F. Mathieu, L. Mazenq, G. Larrieu, Combining PEDOT: PSS polymer coating with metallic 3D nanowires electrodes to achieve high electrochemical performances for neuronal interfacing applications. Adv. Mater. 35, e2302472 (2023).

    [34] Z. Wang, M. Tian, J. Yu, J. Jiao, C. Yang et al., Recent advances of 3D compressible carbon assemblies: a review of synthesis, properties and applications in energy and environment. J. Environ. Chem. Eng. 9, 106269 (2021).

    [35] A.G. El-Shamy, Review on the recent advance in PEDOT: PSS/Carbonic fillers based nanocomposite for flexible thermoelectric devices and sensors. Mater. Today Phys. 35, 101101 (2023).

    [36] X. Xie, R. Guo, B. Yang, H. Li, F. Yang et al., Stencil-printed electrodes without current collectors and inactive additives on textiles for in-plane microsupercapacitors. J. Mater. Chem. A 9, 25042–25050 (2021).

    [37] B. Yang, J. Chen, S. Lei, R. Guo, H. Li et al., Spontaneous growth of 3D framework carbon from sodium citrate for high energy- and power-density and long-life sodium-ion hybrid capacitors. Adv. Energy Mater. 8, 1702409 (2018).

    [38] R. Guo, Y. Yu, Z. Xie, X. Liu, X. Zhou et al., Matrix-assisted catalytic printing for the fabrication of multiscale, flexible, foldable, and stretchable metal conductors. Adv. Mater. 25, 3343–3350 (2013).

    [39] J. Li, J. Cao, B. Lu, G. Gu, 3D-printed PEDOT: PSS for soft robotics. Nat. Rev. Mater. 8, 604–622 (2023).

    [40] W. Cheng, Y. Liu, Z. Tong, Y. Zhu, K. Cao et al., Micro-interfacial polymerization of porous PEDOT for printable electronic devices. EcoMat 5, e12288 (2023).

    [41] T. Su, N. Liu, D. Lei, L. Wang, Z. Ren et al., Flexible MXene/bacterial cellulose film sound detector based on piezoresistive sensing mechanism. ACS Nano 16, 8461–8471 (2022).

    [42] Y. Zheng, R. Yin, Y. Zhao, H. Liu, D. Zhang et al., Conductive MXene/cotton fabric based pressure sensor with both high sensitivity and wide sensing range for human motion detection and E-skin. Chem. Eng. J. 420, 127720 (2021).

    [43] M. Liu, X. Pu, C. Jiang, T. Liu, X. Huang et al., Large-area all-textile pressure sensors for monitoring human motion and physiological signals. Adv. Mater. 29, 1703700 (2017).

    [44] S. Wang, X. Du, Y. Luo, S. Lin, M. Zhou et al., Hierarchical design of waterproof, highly sensitive, and wearable sensing electronics based on MXene-reinforced durable cotton fabrics. Chem. Eng. J. 408, 127363 (2021).

    [45] G. Tian, K. Xu, Y. Huang, X. You, W. Yu et al., An organic/inorganic coating strategy that greatly enhanced sensing performances and reliability of all-fabric piezoresistive sensors. J. Mater. Chem. A 11, 21333–21344 (2023).

    [46] J.V. Vaghasiya, C.C. Mayorga-Martinez, J. Vyskočil, M. Pumera, Black phosphorous-based human-machine communication interface. Nat. Commun. 14, 2 (2023).

    [47] Z. Yang, H. Li, S. Zhang, X. Lai, X. Zeng, Superhydrophobic MXene@carboxylated carbon nanotubes/carboxymethyl chitosan aerogel for piezoresistive pressure sensor. Chem. Eng. J. 425, 130462 (2021).

    [48] M. Yang, Y. Cheng, Y. Yue, Y. Chen, H. Gao et al., High-performance flexible pressure sensor with a self-healing function for tactile feedback. Adv. Sci. 9, 2200507 (2022).

    [49] S. Lee, S. Franklin, F.A. Hassani, T. Yokota, M.O.G. Nayeem et al., Nanomesh pressure sensor for monitoring finger manipulation without sensory interference. Science 370, 966–970 (2020).

    [50] K. Meng, X. Xiao, W. Wei, G. Chen, A. Nashalian et al., Wearable pressure sensors for pulse wave monitoring. Adv. Mater. 34, 2109357 (2022).

    [51] C. Ozsancak, P. Auzou, K. Dujardin, N. Quinn, A. Destée, Orofacial apraxia in corticobasal degeneration, progressive supranuclear palsy, multiple system atrophy and Parkinson’s disease. J. Neurol. 251, 1317–1323 (2004).

    [52] G. Khodabandelou, P.-G. Jung, Y. Amirat, S. Mohammed, Attention-based gated recurrent unit for gesture recognition. IEEE Trans. Autom. Sci. Eng. 18, 495–507 (2021).

    [53] G. Tang, Q. Shi, Z. Zhang, T. He, Z. Sun et al., Hybridized wearable patch as a multi-parameter and multi-functional human-machine interface. Nano Energy 81, 105582 (2021).

    [54] S.-D. Wu, S.-H. Hsu, B. Ketelsen, S.C. Bittinger, H. Schlicke et al., Fabrication of eco-friendly wearable strain sensor arrays via facile contact printing for healthcare applications. Small Meth. 7, 2300170 (2023).

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    Bowen Zheng, Ruisheng Guo, Xiaoqiang Dou, Yueqing Fu, Bingjun Yang, Xuqing Liu, Feng Zhou. Blade-Coated Porous 3D Carbon Composite Electrodes Coupled with Multiscale Interfaces for Highly Sensitive All-Paper Pressure Sensors[J]. Nano-Micro Letters, 2024, 16(1): 267
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