Non-Metallic Triboelectric Patch as a Haptic Sensor for Diversified Applications

Vigneshwaran Mohan , Rence Painappallil Reji , Karthikeyan Krishnamoorthy , Yuvaraj Sivalingam , Surya Velappa Jayaraman , Sang-Jae Kim

Carbon Neutralization ›› 2025, Vol. 4 ›› Issue (5) : e70038

PDF
Carbon Neutralization ›› 2025, Vol. 4 ›› Issue (5) : e70038 DOI: 10.1002/cnl2.70038
RESEARCH ARTICLE

Non-Metallic Triboelectric Patch as a Haptic Sensor for Diversified Applications

Author information +
History +
PDF

Abstract

The growing demand for clean and sustainable energy sources, triboelectric nanogenerators (TENGs) have emerged as an efficient solution for harvesting electrical energy from biomechanical motion. In this study, we report the fabrication of TENG using sonochemically prepared graphene/polydimethylsiloxane (SGP) nanocomposite films as an active tribo-negative layer and polyethylene oxide (PEO) as a tribo-positive layer. The nanocomposite film with 0.75 wt% graphene exhibited superior triboelectric performance, achieving a high output voltage of 415 V and a current of 5.06 µA, respectively. The surface potential characteristics and charge transfer behaviour were systematically studied using Kelvin probe force microscopy (KPFM) and density functional theory (DFT) simulations, suggesting enhanced charge-trapping capability in the nanocomposite film is due to the presence of graphene in the polymer matrix. The fabricated SGP-TENG was successfully integrated into practical applicability such as human motion monitoring, gaming interfaces, and power-point control confirming its potential in futuristic self-powered systems.

Keywords

DFT / energy harvesting / graphene/PDMS / self-powered sensor / triboelectric nanogenerator

Cite this article

Download citation ▾
Vigneshwaran Mohan, Rence Painappallil Reji, Karthikeyan Krishnamoorthy, Yuvaraj Sivalingam, Surya Velappa Jayaraman, Sang-Jae Kim. Non-Metallic Triboelectric Patch as a Haptic Sensor for Diversified Applications. Carbon Neutralization, 2025, 4(5): e70038 DOI:10.1002/cnl2.70038

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

S. Mahalingam, A. Manap, K. S. Lau, et al., “Review of Bioresource-based Conductive Composites,” Renewable and Sustainable Energy Reviews 189 (2024): 113999.
[2]

H. Guo, M. H. Yeh, Y. Zi, et al., “Ultralight Cut-Paper-Based Self-Charging Power Unit for Self-Powered Portable Electronic and Medical Systems,” ACS Nano 11 (2017): 4475–4482.
[3]

C. Wu, A. C. Wang, W. Ding, H. Guo, and Z. L. Wang, “Triboelectric Nanogenerator: A Foundation of the Energy for the New Era,” Advanced Energy Materials 9 (2019): 1802906.
[4]

J. Luo and Z. L. Wang, “Recent Progress of Triboelectric Nanogenerators: From Fundamental Theory to Practical Applications,” EcoMat 2 (2020): e12059.
[5]

L. Chen, C. Chen, L. Jin, et al., “Stretchable Negative Poisson's Ratio Yarn for Triboelectric Nanogenerator for Environmental Energy Harvesting and Self-Powered Sensor,” Energy & Environmental Science 14 (2021): 955–964.
[6]

H. Chen, Q. Lu, X. Cao, N. Wang, and Z. L. Wang, “Natural Polymers Based Triboelectric Nanogenerator for Harvesting Biomechanical Energy and Monitoring Human Motion,” Nano Research 15 (2022): 2505–2511.
[7]

Z. Zheng, D. Yu, B. Wang, and Y. Guo, “Ultrahigh Sensitive, Eco-Friendly, Transparent Triboelectric Nanogenerator for Monitoring Human Motion and Vehicle Movement,” Chemical Engineering Journal 446 (2022): 137393.
[8]

Y. Li, M. Yao, Y. Luo, et al., “Polydopamine-Reinforced Hemicellulose-Based Multifunctional Flexible Hydrogels for Human Movement Sensing and Self-Powered Transdermal Drug Delivery,” ACS Applied Materials & Interfaces 15 (2023): 5883–5896.
[9]

J. Han, N. Xu, J. Yu, et al., “Energy Autonomous Paper Modules and Functional Circuits,” Energy & Environmental Science 15 (2022): 5069–5081.
[10]

Y. Cheng, B. Jiang, S. Chaemchuen, F. Verpoort, and Z. Kou, “Advances and Challenges in Designing Mxene Quantum Dots for Sensors,” Carbon Neutralization 2 (2023): 213–234.
[11]

W. Li, L. Kong, M. Xu, et al., “Microsecond-Scale Transient Thermal Sensing Enabled by Flexible Mo1−xWxS2 Alloys,” Research; A Journal of Science and its Applications 7 (2024): 0452.
[12]

W. Li, M. Xu, J. Gao, et al., “Large-Scale Ultra-Robust MoS2 Patterns Directly Synthesized on Polymer Substrate for Flexible Sensing Electronics,” Advanced Materials 35 (2023): 2207447.
[13]

Y. Yu, H. Li, D. Zhao, et al., “Material's Selection Rules for High Performance Triboelectric Nanogenerators,” Materials Today 64 (2023): 61–71.
[14]

R. Zhang and H. Olin, “Material Choices for Triboelectric Nanogenerators: A Critical Review,” EcoMat 2 (2020): e12062.
[15]

Q. Chen, Y. Cao, Y. Lu, et al., “Hybrid Piezoelectric/Triboelectric Wearable Nanogenerator Based on Stretchable PVDF–PDMS Composite Films,” ACS Applied Materials & Interfaces 16 (2024): 6239–6249.
[16]

D. Qi, K. Zhang, G. Tian, B. Jiang, and Y. Huang, “Stretchable Electronics Based on PDMS Substrates,” Advanced Materials 33 (2021): 2003155.
[17]

J. Liu, Y. Yao, X. Li, and Z. Zhang, “Fabrication of Advanced Polydimethylsiloxane-Based Functional Materials: Bulk Modifications and Surface Functionalizations,” Chemical Engineering Journal 408 (2021): 127262.
[18]

C. Lee, S. Yang, D. Choi, W. Kim, J. Kim, and J. Hong, “Chemically Surface-Engineered Polydimethylsiloxane Layer via Plasma Treatment for Advancing Textile-Based Triboelectric Nanogenerators,” Nano Energy 57 (2019): 353–362.
[19]

P. Zhang, L. Deng, H. Zhang, J. He, X. Fan, and Y. Ma, “Enhanced Performance of Triboelectric Nanogenerator With Micro-Rhombic Patterned PDMS for Self-Powered Wearable Sensing,” Advanced Materials Interfaces 9 (2022): 2201265.
[20]

D. Tantraviwat, P. Buarin, S. Suntalelat, et al., “Highly Dispersed Porous Polydimethylsiloxane for Boosting Power-Generating Performance of Triboelectric Nanogenerators,” Nano Energy 67 (2020): 104214.
[21]

H. Zhu, J. Liang, W. Long, F. Zeng, X. Zhang, and Z. Chen, “Enhancing PDMS-Based Triboelectric Nanogenerator Output by Optimizing the Microstructure and Dielectric Constant,” Journal of Materials Chemistry C 12 (2024): 1782–1791.
[22]

D. Wang, Y. Lin, D. Hu, P. Jiang, and X. Huang, “Multifunctional 3D-MXene/PDMS Nanocomposites for Electrical, Thermal and Triboelectric Applications,” Composites, Part A: Applied Science and Manufacturing 130 (2020): 105754.
[23]

K. Shi, H. Zou, B. Sun, P. Jiang, J. He, and X. Huang, “Dielectric Modulated Cellulose Paper/PDMS-Based Triboelectric Nanogenerators for Wireless Transmission and Electropolymerization Applications,” Advanced Functional Materials 30 (2020): 1904536.
[24]

M. P. Kim, C. W. Ahn, Y. Lee, K. Kim, J. Park, and H. Ko, “Interfacial Polarization-Induced High-k Polymer Dielectric Film for High-Performance Triboelectric Devices,” Nano Energy 82 (2021): 105697.
[25]

T. Ma, H. Gao, H. Cong, et al., “A Bioinspired Interface Design for Improving the Strength and Electrical Conductivity of Graphene-Based Fibers,” Advanced Materials 30 (2018): 1706435.
[26]

Q. Fang, Y. Shen, and B. Chen, “Synthesis, Decoration and Properties of Three-Dimensional Graphene-Based Macrostructures: A Review,” Chemical Engineering Journal 264 (2015): 753–771.
[27]

K. Krishnamoorthy, V. K. Mariappan, P. Pazhamalai, S. Sahoo, and S. J. Kim, “Mechanical Energy Harvesting Properties of Free-Standing Carbyne Enriched Carbon Film Derived From Dehydrohalogenation of Polyvinylidene Fluoride,” Nano Energy 59 (2019): 453–463.
[28]

H. Chen, Y. Xu, J. Zhang, W. Wu, and G. Song, “Enhanced Stretchable Graphene-Based Triboelectric Nanogenerator via Control of Surface Nanostructure,” Nano Energy 58 (2019): 304–311.
[29]

A. N. Parvez, M. H. Rahaman, H. C. Kim, and K. K. Ahn, “Optimization of Triboelectric Energy Harvesting From Falling Water Droplet Onto Wrinkled Polydimethylsiloxane-Reduced Graphene Oxide Nanocomposite Surface,” Composites, Part B: Engineering 174 (2019): 106923.
[30]

V. Mohan, P. Pazhamalai, K. Krishnamoorthy, and S.-J. Kim, “Free-Standing Graphene Oxide/Carboxymethyl Cellulose Paper-Based Triboelectric Nanogenerator for Self-Powered Motion Sensor,” Surfaces and Interfaces 51 (2024): 104553.
[31]

K. Krishnamoorthy, G.-S. Kim, and S. J. Kim, “Graphene Nanosheets: Ultrasound Assisted Synthesis and Characterization,” Ultrasonics Sonochemistry 20 (2013): 644–649.
[32]

V. Mohan, V. K. Mariappan, P. Pazhamalai, K. Krishnamoorthy, and S.-J. Kim, “Unravelling the Impact of Carbon Allotropes in Flexible Polydimethylsiloxane Film Towards Self-Powered Triboelectric Humidity Sensor,” Carbon 205 (2023): 328–335.
[33]

G. E. S. M. J. Frisch, G. W. Trucks, H. B. Schlegel, et al., Gaussian 16, Revision C.01 (Gaussian, Inc., 2016).
[34]

R. P. Reji, G. Marappan, Y. Sivalingam, and V. Jayaraman Surya, “VOCs Adsorption Induced Surface Potential Changes on Phthalocyanines: A Combined Experimental and Theoretical Approach Towards Food Freshness Monitoring,” Materials Letters 306 (2022): 130945.
[35]

N. Kumar Das and S. Badhulika, “Recyclable Waste Derived Green Triboelectric Nanogenerator for Self-Powered Synthesis of Defect-Free Graphene via Mechano-Electrochemical Exfoliation,” Chemical Engineering Journal 480 (2024): 147897.
[36]

E. Aliyev, V. Filiz, M. M. Khan, Y. J. Lee, C. Abetz, and V. Abetz, “Structural Characterization of Graphene Oxide: Surface Functional Groups and Fractionated Oxidative Debris,” Nanomaterials 9 (2019): 1180.
[37]

S. C. T. Zhi-Min Dang, C.-W. Nan, D. Xie, and Y.-H. Zhang, “Dielectric Behavior and Dependence of Percolation Threshold on the Conductivity of Fillers in Polymer-Semiconductor Composites,” Applied Physics Letters 85 (2004): 97.
[38]

K. Kesavan, C. M. Mathew, and S. Rajendran, “Lithium Ion Conduction and Ion-Polymer Interaction in Poly(Vinyl Pyrrolidone) Based Electrolytes Blended With Different Plasticizers,” Chinese Chemical Letters 25 (2014): 1428–1434.
[39]

I. S. Elashmawi and L. H. Gaabour, “Raman, Morphology and Electrical Behavior of Nanocomposites Based on PEO/PVDF With Multi-Walled Carbon Nanotubes,” Results in Physics 5 (2015): 105–110.
[40]

B. Mahanty, S. K. Ghosh, and D.-W. Lee, “Boosted Triboelectric Performance in Stretchable Nanogenerators via 2D Mxene-Driven Electron Accumulation and LiNbO₃-Assisted Charge Transfer,” Composites, Part B: Engineering 291 (2025): 111995.
[41]

A. Kaur, S. Singh, P. Sharma, A. Gupta, and G. Sapra, “Density Functional Theory and Experimental Investigations of MWCNT-PDMS Based Triboelectric Nanogenerator,” Materials Today Communications 33 (2022): 104742.
[42]

Y. Sivalingam, P. Elumalai, S. V. J. Yuvaraj, et al., “Interaction of VOCs With Pyrene Tetratopic Ligands Layered on ZnO Nanorods Under Visible Light,” Journal of Photochemistry and Photobiology, A: Chemistry 324 (2016): 62–69.
[43]

S. Sasi, P. Palanisamy, R. P. Reji, et al., “Porphyrinoid-Functionalized ZnO Nanoflowers for Visible Light-Enhanced and Selective Benzylamine Detection at Room Temperature,” ACS Applied Materials & Interfaces 16 (2024): 61204–61217.
[44]

P. Ding, J. Chen, U. Farooq, et al., “Realizing the Potential of Polyethylene Oxide as New Positive Tribo-Material: Over 40 W/m2 High Power Flat Surface Triboelectric Nanogenerators,” Nano Energy 46 (2018): 63–72.
[45]

L. Shi, S. Dong, P. Ding, et al., “Carbon Electrodes Enable Flat Surface PDMS and PA6 Triboelectric Nanogenerators to Achieve Significantly Enhanced Triboelectric Performance,” Nano Energy 55 (2019): 548–557.
[46]

V. K. Mariappan, K. Krishnamoorthy, P. Pazhamalai, S. Manoharan, and S.-J. Kim, “Decoupling Contact and Rotary Triboelectrification vs Materials Property: Toward Understanding the Origin of Direct-Current Generation in TENG,” ACS Applied Materials & Interfaces 14 (2022): 34593–34602.
[47]

R. D. I. G. Dharmasena, J. H. B. Deane, and S. R. P. Silva, “Nature of Power Generation and Output Optimization Criteria for Triboelectric Nanogenerators,” Advanced Energy Materials 8 (2018): 1802190.
[48]

M. R. Islam, O. Faruk, S. M. S. Rana, et al., “Poly-DADMAC Functionalized Polyethylene Oxide Composite Nanofibrous Mat as Highly Positive Material for Triboelectric Nanogenerators and Self-Powered Pressure Sensors,” Advanced Functional Materials 34 (2024): 2403899.

RIGHTS & PERMISSIONS

2025 The Author(s). Carbon Neutralization published by Wenzhou University and John Wiley & Sons Australia, Ltd.

AI Summary AI Mindmap
PDF

21

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/