Fan, F. et al. Flexible triboelectric generator. Nano Energy1, 328–334 (2012). To our knowledge, this paper is the first about the triboelectric generator, which can convert mechanical energy into electricity in the energy harvesting field. Article Google Scholar
Wang, Z. L. From contact-electrification to triboelectric nanogenerators. Rep. Prog. Phys.84, 096502 (2021). This paper presents a comprehensive summary of the fundamental science and working mechanism as well as important experiments of TENGs. ArticleADSMathSciNet Google Scholar
Wang, Z. L. Triboelectric nanogenerator (TENG) — sparking an energy and sensor revolution. Adv. Energy Mater.10, 2000137 (2020). Article Google Scholar
Wang, Z. L. et al. Triboelectric Nanogenerators (Springer, 2016).
Shao, J., Willatzen, M. & Wang, Z. L. Theoretical modelling of triboelectric nanogenerators (TENGs). J. Appl. Phys.128, 111101 (2020). ArticleADS Google Scholar
Cheng, G., Lin, Z., Du, Z. & Wang, Z. L. Simultaneously harvesting electrostatic and mechanical energies from flowing water by a hybridized triboelectric nanogenerator. ACS Nano8, 1932–1939 (2014). Article Google Scholar
Guo, H. et al. A water-proof triboelectric–electromagnetic hybrid generator for energy harvesting in harsh environments. Adv. Energy Mater.6, 1501593 (2016). Article Google Scholar
Yang, J. et al. Triboelectrification-based organic film nanogenerator for acoustic energy harvesting and self-powered active acoustic sensing. ACS Nano8, 2649–2657 (2014). Article Google Scholar
Yang, P. et al. Paper-based origami triboelectric nanogenerators and self-powered pressure sensors. ACS Nano9, 901–907 (2015). This paper is a selected representative work about TENGs, which can be used as self-powered sensors for characterizing mechanical triggers under external mechanical triggering. Article Google Scholar
Xu, L. et al. Coupled triboelectric nanogenerator networks for efficient water wave energy harvesting. ACS Nano12, 1849–1858 (2018). Article Google Scholar
Liu, L. et al. Nodding duck structure multi-track directional freestanding triboelectric nanogenerator toward low-frequency ocean wave energy harvesting. ACS Nano15, 9412–9421 (2021). Article Google Scholar
Cheng, J. et al. Triboelectric microplasma powered by mechanical stimuli. Nat. Commun9, 3733 (2018). This work introduces a typical characteristic of TENGs, their high output voltage. ArticleADS Google Scholar
Bai, Y. et al. Washable multilayer triboelectric air filter for efficient particulate matter PM2.5 removal. Adv. Funct. Mater.28, 1706680 (2018). Article Google Scholar
Lin, S. & Wang, Z. L. Scanning triboelectric nanogenerator as a nanoscale probe for measuring local surface charge density on a dielectric film. Appl. Phys. Lett.118, 193901 (2021). ArticleADS Google Scholar
Zhang, J., Lin, S., Zheng, M. & Wang, Z. L. Triboelectric nanogenerator as a probe for measuring the charge transfer between liquid and solid surfaces. ACS Nano15, 14830–14837 (2021). This work verifies that a single-electrode TENG can be a probe for measuring the charge transfer at a liquid–solid interface. Article Google Scholar
Dharmasena, R. D. I. G. et al. Triboelectric nanogenerators: providing a fundamental framework. Energy Environ. Sci.10, 1801 (2017). Article Google Scholar
Dharmasena, R. D. et al. Nature of power generation and output optimization criteria for triboelectric nanogenerators. Adv. Energy Mater.8, 1802190 (2018). Article Google Scholar
Shao, J., Willatzen, M., Shi, Y. & Wang, Z. L. 3D mathematical model of contact-separation and single-electrode mode triboelectric nanogenerators. Nano Energy60, 630–640 (2019). To our knowledge, this paper establishes the first 3D mathematical model based on Maxwell’s equations of TENGs. Article Google Scholar
Shao, J., Liu, D., Willatzen, M. & Wang, Z. L. Three-dimensional modeling of alternating current triboelectric nanogenerator in the linear sliding mode. Appl. Phys. Rev.7, 011405 (2020). ArticleADS Google Scholar
Wang, Z. L. et al. On the origin of contact-electrification. Mater. Today30, 34–51 (2019). Article Google Scholar
Shao, J. et al. Designing rules and optimization of triboelectric nanogenerator arrays. Adv. Energy Mater.11, 2100065 (2021). This paper presents universal design rules and holistic optimization strategies for the network structure of TENGs, which is used as micro and nano-power sources. Article Google Scholar
Shao, J. et al. Structural figure-of-merits of triboelectric nanogenerators at powering loads. Nano Energy51, 688 (2018). Article Google Scholar
Shao, J., Jiang, T. & Wang, Z. L. Theoretical foundations of triboelectric nanogenerators (TENGs). Sci. China. Technol. Sci. 63, 1087–1109 (2020). ArticleADS Google Scholar
Guo, X. et al. Three-dimensional mathematical modelling and dynamic analysis of freestanding triboelectric nanogenerators. J. Phys. D Appl. Phys.55, 345501 (2022). Article Google Scholar
Guo, X. et al. Theoretical model and optimal output of a cylindrical triboelectric nanogenerator. Nano Energy92, 106762 (2022). Article Google Scholar
Wang, Z. L. Maxwell’s equations for a mechano-driven, shape-deformable, charged media system, slowly moving at an arbitrary velocity field v(r, t). J. Phys. Commun.6, 085013 (2022). Article Google Scholar
Wang, Z. L. & Shao, J. Maxwell’s equations for a mechano-driven varying-speed motion media system under slow motion and nonrelativistic approximations [Chinese]. Sci. Sin. Tech.52, 1198–1211 (2022). Article Google Scholar
Wang, Z. L. & Shao, J. Maxwell’s equations for a mechano-driven varying-speed-motion media system for engineering electrodynamics and their solutions [Chinese]. Sci. Sin. Tech.52, 1416–1433 (2022). Article Google Scholar
Wang, Z. L. On the first principle theory of nanogenerators from Maxwell’s equations. Nano Energy68, 104272 (2020). To our knowledge, this work presents the first principle theory of TENGs from Maxwell’s equations. Article Google Scholar
Wang, Z. L. On the expanded Maxwell’s equations for moving charged media system — general theory, mathematical solutions and applications in TENG. Mater. Today52, 348–363 (2021). Article Google Scholar
Wang, H. et al. A paradigm-shift fully-self-powered long-distance wireless sensing solution enabled by discharge induced displacement current. Sci. Adv.7, eabi6751 (2021). ArticleADS Google Scholar
Cao, X. et al. An easy and efficient power generator with ultrahigh voltage for lighting, charging and self-powered systems. Nano Energy100, 107409 (2022). Article Google Scholar
Zhao, H. et al. Underwater wireless communication via TENG-generated Maxwell’s displacement current. Nat. Commun.13, 3325 (2022). ArticleADS Google Scholar
Shao, J. et al. Quantifying the power output and structural figure-of-merits of triboelectric nanogenerators in a charging system starting from the Maxwell’s displacement current. Nano Energy59, 380–389 (2019). Article Google Scholar
Niu, S. et al. Theoretical study of contact-mode triboelectric nanogenerators as an effective power source. Energy Environ. Sci.6, 3576 (2013). To our knowledge, this work proposes the first equivalent circuit model of TENGs. Article Google Scholar
Niu, S. et al. Theoretical investigation and structural optimization of single-electrode triboelectric nanogenerators. Adv. Funct.Mater.24, 3332–3340 (2014). Article Google Scholar
Niu, S. et al. Theory of sliding-mode triboelectric nanogenerators. Adv.Mater.25, 6184–6193 (2013). Article Google Scholar
Niu, S. et al. Theory of freestanding triboelectric-layer-based nanogenerators. Nano Energy12, 760–774 (2015). Article Google Scholar
Jiang, T. et al. Figures-of-merit for rolling-friction-based triboelectric nanogenerators. Adv. Mater. Technol.1, 1600017 (2016). Article Google Scholar
Chen, B. et al. Water wave energy harvesting and self-powered liquid-surface fluctuation sensing based on bionic-jellyfish triboelectric nanogenerator. Mater. Today21, 88–97 (2018). Article Google Scholar
Niu, S. & Wang, Z. L. Theoretical systems of triboelectric nanogenerators. Nano Energy14, 161 (2015). Article Google Scholar
Peng, J., Kang, S. D. & Snyder, G. J. Optimization principles and the figure of merit for triboelectric generators. Sci. Adv.3, eaap8576 (2017). ArticleADS Google Scholar
Zi, Y. L. et al. Standards and figure-of-merits for quantifying the performance of triboelectric nanogenerators. Nat. Commun.6, 8376 (2015). ArticleADS Google Scholar
Li, X. et al. Stimulation of ambient energy generated electric field on crop plant growth. Nat. Food3, 133–142 (2022). Article Google Scholar
Rana, S. M. S. et al. Ultrahigh-output triboelectric and electromagnetic hybrid generator for self-powered smart electronics and biomedical applications. Adv. Energy Mater.12, 2202238 (2022). Article Google Scholar
Chen, P. et al. Achieving high power density and durability of sliding mode triboelectric nanogenerator by double charge supplement strategy. Adv. Energy Mater.12, 2201813 (2022). Article Google Scholar
Zhang, X. et al. Broadband vibration energy powered autonomous wireless frequency monitoring system based on triboelectric nanogenerators. Nano Energy98, 107209 (2022). Article Google Scholar
Guo, Y. et al. Multifunctional mechanical sensing electronic device based on triboelectric anisotropic crumpled nanofibrous mats. ACS Appl. Mater. Interfaces13, 55481–55488 (2021). Article Google Scholar
Zhang, D. et al. Multi-grating triboelectric nanogenerator for harvesting low-frequency ocean wave energy. Nano Energy61, 132–140 (2019). ArticleADS Google Scholar
Guo, H. et al. An ultrarobust high-performance triboelectric nanogenerator based on charge replenishment. ACS Nano9, 5577–5584 (2015). Article Google Scholar
Lin, Z. et al. Super-robust and frequency-multiplied triboelectric nanogenerator for efficient harvesting water and wind energy. Nano Energy64, 103908 (2019). Article Google Scholar
Yang, J. et al. Broadband vibrational energy harvesting based on a triboelectric nanogenerator. Adv. Energy Mater.4, 1301322 (2014). ArticleMathSciNet Google Scholar
Liang, X. et al. Spherical triboelectric nanogenerator integrated with power management module for harvesting multidirectional water wave energy. Energy Environ. Sci.13, 277–285 (2020). Article Google Scholar
Han, J. et al. Energy autonomous paper modules and functional circuits. Energy Environ. Sci.15, 5069 (2022). Article Google Scholar
Zi, Y. et al. Effective energy storage from a triboelectric nanogenerator. Nat. Commun.7, 10987 (2016). ArticleADS Google Scholar
Ren, Z. et al. Water‐wave driven route avoidance warning system for wireless ocean navigation. Adv. Energy Mater.11, 2101116 (2021). ArticleADSMathSciNet Google Scholar
Cheng, R. et al. Enhanced output of on-body direct-current power textiles by efficient energy management for sustainable working of mobile electronics. Adv. Energy Mater.12, 2201532 (2022). Article Google Scholar
Liang, X., Liu, S., Ren, Z., Jiang, T. & Wang, Z. L. Self-powered intelligent buoy based on triboelectric nanogenerator for water level alarming. Adv. Funct. Mater.32, 2205313 (2022). Article Google Scholar
Xi, F. et al. Self-powered intelligent buoy system by water wave energy for sustainable and autonomous wireless sensing and data transmission. Nano Energy61, 1–9 (2019). Article Google Scholar
Zhang, X. et al. Harvesting multidirectional breeze energy and self-powered intelligent fire detection systems based on triboelectric nanogenerator and fluid-dynamic modeling. Adv. Funct. Mater. 31, 2106527 (2021). Article Google Scholar
Li, C. et al. Sensing of joint and spinal bending or stretching via a retractable and wearable badge reel. Nat. Commun.12, 2950 (2021). ArticleADS Google Scholar
Yang, J. et al. 3D-printed bearing structural triboelectric nanogenerator for intelligent vehicle monitoring. Cell Rep. Phys. Sci.2, 100666 (2021). Article Google Scholar
Wang, Z. et al. A self-powered angle sensor at nanoradian-resolution for robotic arms and personalized medicare. Adv. Mater.13, 2001466 (2020). Article Google Scholar
Peng, X. et al. All-nanofiber self-powered skin-interfaced real-time respiratory monitoring system for obstructive sleep apnea-hypopnea syndrome diagnosing. Adv. Funct. Mater.20, 2103559 (2021). Article Google Scholar
Wang, Z. L. Triboelectric nanogenerators as new energy technology and self-powered sensors — principles, problems and perspectives. Faraday Discuss176, 447–485 (2014). ArticleADS Google Scholar
Wang, Z. L. Nanogenerators, self-powered systems, blue energy, piezotronics and piezophototronics — a recall on the original thoughts for coining these fields. Nano Energy54, 477–483 (2018). Article Google Scholar
Yang, X. et al. Macroscopic self-assembly network of encapsulated high-performance triboelectric nanogenerators for water wave energy harvesting. Nano Energy60, 404–412 (2019). Article Google Scholar
Wang, H., Xu, L., Bai, Y. & Wang, Z. L. Pumping up the charge density of a triboelectric nanogenerator by charge-shuttling. Nat. Commun.11, 4203 (2020). ArticleADS Google Scholar
Jiang, T. et al. Robust swing-structured triboelectric nanogenerator for efficient blue energy harvesting. Adv. Energy Mater.10, 2000064 (2020). ArticleADS Google Scholar
Wang, Z. L., Jiang, T. & Xu, L. Toward the blue energy dream by triboelectric nanogenerator networks. Nano Energy39, 9–23 (2017). This paper introduces one of the important uses of TENGs to harvest energy from the ocean or wave energy. Article Google Scholar
Lei, R. et al. Sustainable high-voltage source based on triboelectric nanogenerator with a charge accumulation strategy. Energy Environ. Sci13, 2178–2190 (2020). Article Google Scholar
Xu, L. et al. Giant voltage enhancement via triboelectric charge supplement channel for self-powered electroadhesion. ACS Nano12, 10262–10271 (2018). Article Google Scholar
Li, D. et al. Interface inter-atomic electron-transition induced photon emission in contact-electrification. Sci. Adv.7, eabj0349 (2021). ArticleADS Google Scholar
Nan, Y. et al. Physical mechanisms of contact-electrification induced photon emission spectroscopy from interfaces. Nano Res.https://doi.org/10.1007/s12274-023-5674-2 (2023).
Wang, Z. et al. Contact-electro-catalysis for the degradation of organic pollutants using pristine dielectric powders. Nat. Commun.13, 130 (2022). ArticleADS Google Scholar
Zou, H. et al. Quantifying the triboelectric series. Nat. Commun.10, 1427 (2019). ArticleADS Google Scholar
Zou, H. et al. Quantifying and understanding the triboelectric series of inorganic non-metallic materials. Nat. Commun.11, 2093 (2020). ArticleADS Google Scholar
Wang, Z. L., Chen, J. & Lin, L. Progress in triboelectric nanogenerators as new energy technology and self-powered sensors. Energy Environ. Sci.8, 2250 (2015). Article Google Scholar
Lin, S., Chen, X. & Wang, Z. L. Contact electrification at the liquid–solid interface. Chem. Rev.122, 5209–5232 (2022). Article Google Scholar
Liu, J. et al. Direct-current triboelectricity generation by a sliding schottky nanocontact on MoS2 multilayers. Nat. Nanotechnol13, 112–116 (2018). ArticleADS Google Scholar
Hao, Z. et al. Co-harvesting light and mechanical energy based on dynamic metal/perovskite Schottky junction. Matter1, 639–649 (2019). Article Google Scholar
Lin, S., Chen, X. & Wang, Z. L. The tribovoltaic effect and electron transfer at a liquid–semiconductor interface. Nano Energy76, 105070 (2020). Article Google Scholar
Xu, R. et al. Direct current triboelectric cell by sliding an n-type semiconductor on a p-type semiconductor. Nano Energy66, 104185 (2019). Article Google Scholar
Zhang, Z. et al. Tribovoltaic effect on metal–semiconductor interface for direct-current low-impedance triboelectric nanogenerators. Adv. Energy Mater.10, 1903713 (2020). Article Google Scholar
Zhang, Z. et al. Tribo-thermoelectric and tribovoltaic coupling effect at metal–semiconductor interface. Mater. Today Phys.16, 100295 (2021). Article Google Scholar
Zheng, M. et al. Photovoltaic effect and tribovoltaic effect at liquid–semiconductor interface. Nano Energy83, 105810 (2021). Article Google Scholar