Breathable Nanogenerators for an On-Plant Self-Powered Sustainable Agriculture System

Lan, Lingyi; Xiong, Jiaqing; Gao, Daquan; Li, Yi; Chen, Jian; Lv, Jian; Ping, Jianfeng; Ying, Yibin; Lee, Pooi See

doi:10.1021/acsnano.0c10817

Cited by 124 publications

(102 citation statements)

References 40 publications

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Section: Cellulose‐inspired On‐spot Tengs Based On Plantsmentioning

confidence: 99%

“…Therefore, Lan and Xiong et al described a waterproof and breathable fiber‐based TENG (WB‐TENG) to establish an intelligent interface between plants and the environment for real‐time monitoring of plant health and harvesting natural energy (Figure 12b). [ 213 ] By means of the electrospinning and electrospraying method, a composite layer‐structured PVDF fiber film with adjustable components and morphology was produced; the hydrophobic functional components of fluorinated CNT could be combined between the nanofibers, but it also boosted the roughness. In addition to good environmental adaptability of the TENG, the key was that it can self‐attach on the plant and not affect the health of the plant; stable output performance was proved when the WB‐TENG adhered to the plant for 55 days.…”

Section: Cellulose‐inspired On‐spot Tengs Based On Plantsmentioning

confidence: 99%

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Cellulose for Sustainable Triboelectric Nanogenerators

Zhou

Wang

et al. 2021

Adv Energy and Sustain Res

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Triboelectric nanogenerators (TENGs) are an emerging technology capable of converting the ambient mechanical energy into electricity, promising for complete utilization of the distributed energy to improve the quality of human life. However, realizing material innovation for good trade‐off between the high triboelectric output and environment friendliness remains huge challenge, but it is of great importance for sustainable development of TENGs. Cellulose is a typical natural polymer that promises to address the challenge. Herein, the sustainable TENGs that originate from cellulose and potentially back to the natural world are focused on, realizing on‐spot TENGs. First, the sources, forms, morphologies, structures, and modifications of cellulose are systematically summarized, indicating the commercial and noncommercial cellulose materials’ potential for TENGs’ application. Second, the dominating additive properties of cellulose such as hydrophobicity, self‐cleaning, corrosion resistance, optical transparency, electrical conductivity, and degradability are introduced, which can effectively steer the development of TENGs. Thereafter, the TENGs with tailorable functions enabled by less‐refined cellulose and various physical/chemical modified cellulose are reviewed, as well as plants‐supported on‐spot TENGs with environment adaptivity and transient property, embracing a sustainable future of versatile cellulose to adapt the distributed network of multiscenario TENGs for energy management and information communication.

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Section: Cellulose‐inspired On‐spot Tengs Based On Plantsmentioning

confidence: 99%

Section: Cellulose‐inspired On‐spot Tengs Based On Plantsmentioning

confidence: 99%

Cellulose for Sustainable Triboelectric Nanogenerators

Zhou

Wang

et al. 2021

Adv Energy and Sustain Res

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“…Lan et al. [ 172 ] designed a waterproof and breathable TENG (WB‐TENG). It has not only pleasurable mechanical compliance but also high electrostatic adhesion, which can realize the adhesion to plant leaves and convert wind and rain droplets in the environment into electric energy.…”

Section: Sensor Energy Supply and Communication Platformmentioning

confidence: 99%

Flexible Wearables for Plants

Sun

et al. 2021

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The excellent stretchability and biocompatibility of flexible sensors have inspired an emerging field of plant wearables, which enable intimate contact with the plants to continuously monitor the growth status and localized microclimate in real‐time. Plant flexible wearables provide a promising platform for the development of plant phenotype and the construction of intelligent agriculture via monitoring and regulating the critical physiological parameters and microclimate of plants. Here, the emerging applications of plant flexible wearables together with their pros and cons from four aspects, including physiological indicators, surrounding environment, crop quality, and active control of growth, are highlighted. Self‐powered energy supply systems and signal transmission mechanisms are also elucidated. Furthermore, the future opportunities and challenges of plant wearables are discussed in detail.

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“…Additionally, TEHs can also be integrated with many other sensors, such as the wind speed detection sensor [14], the inertial motion sensor [15], the pressure mapping sensor [16], human motion monitoring sensor [17]. Recently, a waterproof and breathable TEH was developed to drive a multifunctional plant sensor and transmit data remotely, which was attached to plant leaves conformally for harvesting energy from wind and raindrops [18]. Apparently, triboelectric energy harvesting has broad application prospects with distinct merits in energy harvesting.…”

Section: Triboelectric Energy Harvestingmentioning

confidence: 99%

Structural and Electrical Dynamics of a Grating-Patterned Triboelectric Energy Harvester with Stick-Slip Oscillation and Magnetic Bistability

Zhao¹,

Ouyang²

2021

Preprint

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The majority of research work on triboelectric energy harvesting is on material science, manufacturing and electric circuit design. There is a lack of in-depth research into structural dynamics which is crucial for power generation in triboelectric energy harvesting. In this paper, a novel triboelectric energy harvester with a compact structure working in sliding mode is developed, which is in the form of a casing and an oscillator inside. Unlike most sliding-mode harvesters using single-unit films, the proposed harvester utilizes grating-patterned films which are much more efficient. A bistable mechanism consisting of two pairs of magnets is employed for broadening the frequency bandwidth. A theoretical model is established for the harvester, which couples the structural dynamics domain and electrical dynamics domain. This paper presents the first study about the nonlinear structural dynamics of a triboelectric energy harvester with grating-patterned films, which is also the first triboelectric energy harvester integrating grating-patterned films with a bistable magnetic system for power performance enhancement. Theoretical studies are carried out from the perspectives of both structural and electrical dynamics. A comparison between the coupled model and uncoupled model reveals that the electrostatic force between the electrodes can be neglected. Great differences in structural response and electrical output are found between a velocity-dependent model and Coulomb’s model for modelling the friction in the harvester. The bistable mechanism can effectively improve the output voltage under low-frequency excitations. Additionally, the output voltage can also be obviously enhanced through increasing the number of the hollowed-out units of the grating-patterned films, which also results in a slight decrease of the optimal load resistance of the harvester. These findings enable innovative designs for triboelectric energy harvesters and provide fabrication guidelines in practical applications.

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Breathable Nanogenerators for an On-Plant Self-Powered Sustainable Agriculture System

Cited by 124 publications

References 40 publications

Cellulose for Sustainable Triboelectric Nanogenerators

Cellulose for Sustainable Triboelectric Nanogenerators

Flexible Wearables for Plants

Structural and Electrical Dynamics of a Grating-Patterned Triboelectric Energy Harvester with Stick-Slip Oscillation and Magnetic Bistability

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