- 1Qingdao Key Laboratory of Groundwater Resources Protection and Rehabilitation, Qingdao, China
- 2Key Laboratory of Geological Safety of Coastal Urban Underground Space, Qingdao, China
- 3Qingdao Geo-Engineering Surveying Institute, Qingdao, China
- 4School of Mechatronic Engineering, Guangdong Polytechnic Normal University, Guangzhou, Guangdong, China
1 Introduction
Agriculture has always been the cornerstone of the global economy, ensuring the essential livelihoods of people (Pang et al., 2021). Advancements in science and technology have facilitated substantial growth in agriculture (Yu and Wu, 2018; Wang et al., 2020). However, this progress has also caused environmental challenges (Shen et al., 2018). Agricultural groundwater pollution refers to the contamination of groundwater due to the release of detrimental substances stemming from agricultural activities, including nitrogen, phosphorus, veterinary drug residues, and bacteria (Baddam et al., 2016; Zhang et al., 2020). Agricultural wastewater, containing elevated levels of nitrogen and phosphorus, can readily induce water body eutrophication, posing a threat to aquatic life and health. When these substances seep into groundwater, they can damage groundwater quality (Li and Zhang, 1999; Baweja et al., 2020). Additionally, agricultural underground wastewater can easily contaminate drinking water sources and endanger the well-being of residents (Baba and Tayfur, 2011; Jiang et al., 2020). Persistent groundwater pollution undermines the sustainable management of groundwater reservoirs, inflicting irreversible harm on groundwater resources. Consequently, it is imperative to establish a robust system for assessing and monitoring environmental quality. Establishing suitable waste monitoring and treatment systems in remote areas is crucial to ensuring the health of residents and the stability of ecosystems.
Currently, environmental monitoring and pollutant treatment technologies have reached a relatively advanced stage. Various methods for environmental monitoring and waste treatment are continuously being introduced and refined. However, it is worth noting that sewage treatment facilities often come with high construction costs and tend to be concentrated near economically developed areas (Berthouex et al., 1978; Molinos-Senante et al., 2010; Jafarinejad, 2017). Furthermore, these monitoring and treatment technologies rely on a continuous supply of electrical energy. In remote mountainous regions, maintaining a consistent power supply is difficult, which, in turn, hampers the real-time monitoring and treatment of waste and put the health of residents at risk. Therefore, the imperative lies in the development of cost-effective, environmentally friendly, and self-powered wastewater monitoring and treatment systems, which hold significant importance in mitigating groundwater pollution in remote agricultural areas and ensuring the well-being of residents.
In 2012, Wang introduced triboelectric nanogenerator (TENG) technology, which harvest mechanical energy from the environment, and converting it into electrical energy through electrostatic induction and triboelectric electrification principles (Niu and Wang, 2015; Zi et al., 2015; Tinghai et al., 2023). TENG generates charge transfer via friction and the contact separation of dissimilar materials, resulting in electric current generation. TENG possesses advantages such as cost-effectiveness, portability, environmental sustainability, and excellent flexibility (Zhu et al., 2015; Cheng et al., 2019; Dharmasena and Silva, 2019; Wu et al., 2019; Wang, 2020; Zhou et al., 2020; Kim et al., 2021). TENG has demonstrated a diverse array of potential applications encompassing wearable devices (Zou et al., 2020; Wang et al., 2021; Dassanayaka et al., 2022), self-powered sensors (Wang, 2014; Wang S. et al., 2015; Wang Z. L. et al., 2015), smart medicine (Jiang et al., 2021; Parandeh et al., 2021; Chen et al., 2022), environmental monitoring (Chen et al., 2020; Zhao et al., 2020; Chang et al., 2022), and wastewater treatment (Chen et al., 2016; Li et al., 2016; Mo et al., 2022). It is also demonstrated that TENG can be integrated into wearable devices to harvest mechanical energy from the human body, thereby powering small electronic devices. TENG’s environmental sustainability and exceptional flexibility position it as a significant asset in the realm of environmental monitoring. In addition, TENG can detect environmental parameters such as water flow and wind speed, relaying this information through electrical signals. Leveraging TENG’s electrical output enables the degradation of various pollutant types. For instance, electrocatalysis can effectively degrade organic water pollutants, while electrospinning membranes excel at adsorbing particulate matter.
In this paper, we firstly summarized the environmental challenges posed by contemporary agricultural production. Then, we introduced the existing environmental monitoring and sewage treatment technologies and discussed their limitations. Besides, we summarized the working principles and application prospects of TENG and introduced the research about TENG in the realms of environmental monitoring and sewage treatment. Further, we examine the crucial issues and prospects of in the realm of environmental engineering.
2 Principles and applications of triboelectric nanogenerator
TENG primarily relies on the contact separation or friction between two dissimilar materials. In general, materials exhibit varying abilities to gain or lose electrons, which is the basis for TENG’s operation. Electron transfer that driven by differences in electronegativity takes place when two dissimilar materials come into contact or move in relation to each other. After separation of the two materials, an electrical potential difference arises between them. The material is linked to an external circuit via electrodes. To equalize the potential difference, electrons traverse the external circuit, thereby generating an electric current (Luo et al., 2021). Consequently, if the two materials maintain constant contact, separation, or relative motion, the TENG can sustain the generation of current. TENG boasts remarkable energy conversion efficiency, accommodates a broad spectrum of materials, and can be applied in diverse sizes and configurations. Its high sensitivity enables it to detect minor environmental changes (Zhou et al., 2020; Mo et al., 2022; Tinghai et al., 2023). Furthermore, the production process for TENG is exceptionally straightforward, resulting in minimal cost consumption. TENG operates in four distinct modes: contact separation mode, sliding friction mode, single electrode mode, and independent layer mode (Cao et al., 2016).
TENG’s environmental friendliness, cost-effectiveness, and exceptional flexibility confer substantial advantages in environmental monitoring, pollutant treatment, and related domains (Cheng et al., 2019). Firstly, TENG serves as a power source for powering environmental monitoring sensors, enabling their operation in remote regions (Zhang et al., 2019; Liang et al., 2022). Moreover, TENG can construct sensor systems for real-time environmental quality assessment, presenting monitoring results via electrical signals (Chang et al., 2022; Liang et al., 2022). TENG can achieve real-time water quality monitoring by capturing environmental water wave energy. Secondly, the electricity produced by TENG can be employed in electrochemical processes for the degradation of organic wastewater pollutants (Chen et al., 2016). Additionally, it can be integrated with electrospinning membranes to absorb environmental particulate matter. Furthermore, TENG can be seamlessly integrated into wearable devices like masks to provide real-time monitoring of the user’s working environment’s environmental quality (Zou et al., 2020).
3 Self-powered system based on TENG for environmental engineering
3.1 Wastewater pollutant monitoring based on TENG
The operational principle of TENG demonstrates significant potential for environment quality monitoring. It is important to note that TENG operates based on differing electronegativities between two materials, which can include solids, liquids, and gas. Consequently, solid-liquid TENGs can be engineered to utilize the movement of liquids, inducing friction between materials, and thereby generating electrical signals. Solid-liquid TENG are suitable for monitoring water quality parameters, including water level and ion concentration. In addition, the use of gas-sensitive materials to produce TENGs can enable real-time monitoring of gas concentrations in the environment. The significant advantage of TENG in environmental sustainability enable prolonged monitoring of environmental parameters.
Pollution in aquatic environments poses a severe threat to ecological stability and human health. Due to the rapid expansion of agriculture, the utilization of chemical fertilizers, pesticides, and similar substances has surged, significantly heightening the potential for harm to surface water and groundwater ecosystems. TENG, recognized for its high sensitivity and environmental friendliness, has demonstrated substantial advantages in water quality assessment. Wang et al. developed a direct-current rotating tubular TENG (DC-rTENG) utilizing liquid dielectric contact for sustainable energy harvesting and chemical composition analysis. Figure 1A depicts its structure. They investigated the design, working mechanism, electrical output performance, and potential applications of this new nanogenerator for detecting the chemical composition of liquid dielectrics. Key findings reveal that DC-rTENG can efficiently harvest low-frequency mechanical energy and is capable of analyzing changes in the chemical composition of liquid dielectrics by monitoring its electrical output. Figure 1B illustrates the electrical output of DC-rTENG when detecting different liquids such as hexane, ethanol, and deionized water. This research presents a new method for energy harvesting and chemical composition analysis, and has the potential to significantly affect environmental monitoring, health diagnostics, and additional fields (Wang et al., 2019). Jiang et al. designed a liquid sensor based on liquid-solid basic mode TENG. The specific structure is shown in Figure 1C. Through this sensor, they successfully identified different types of solutions such as HCl aqueous solution, deionized water, and NaOH. The identification signals are shown in Figure 1D (Jiang et al., 2019). Chen et al. introduced a highly flexible capillary TENG (ct-TENG), a microfluidic sensor with the unique ability to perform non-destructive and highly flexible microliter sampling (with a sampling volume of 0.5 µL). The ct-TENG comprises an ultra-fine tubular sandwich structure involving polytetrafluoroethylene capillary tubes, double-helical aluminum foil, and silicone rubber-sealed tubes (Figure 1E). The generator maintains a stable open-circuit voltage of 1.1V, enabling the detection of 0.5 µL of microliquid. The system can differentiate between bottled water, tap water, and deionized water based on the output electrical signal. Furthermore, it is capable of detecting various ion standard solutions (Figure 1F) (Chen et al., 2018).
Figure 1. (A) Structure diagram of DC-rTENG (Wang et al., 2019). (B) Results of DC-rTENG detecting different liquids (Wang et al., 2019). (C) Structural diagram of liquid-solid contact TENG (Jiang et al., 2019). (D) Results of liquid-solid contact TENG detection of different liquids (Jiang et al., 2019). (E) Structure diagram of microfluidic assay (Chen et al., 2018). (F) Standard ion solution test results (Chen et al., 2018). (G) Schematic diagram of TENG-driven electro-Fenton system (Zhu et al., 2021). (H) Result diagram of pollutant degradation by TENG-driven electro-Fenton system (Zhu et al., 2021). (I) Schematic diagram of a self-powered electrocatalytic system (Dong et al., 2022). (J) New material synthesis and system working principle (Wang et al., 2022).
The output of TENG has been shown to drive the normal operation of water quality monitoring sensors. Rui et al. designed a cylindrical TENG with a gate electrode installed inside that can collect water wave energy. The TENG consists of a stator and a rotor. When the TENG is working, there is relative movement between the stator and the rotor, causing friction. They added an arched FEP film to the rotor to improve the output performance of the TENG. The results show that the TENG can successfully drive hydrological monitoring and wireless data transmission systems. This system design is of great significance to the development of water quality monitoring sensors (Rui et al., 2020). Additionally, TENG can also monitor water levels. Li et al. designed a new type of bubble TENG by moving bubbles in a PTFE tube filled with liquid. The steady movement of bubbles in the tube can continuously generate a stable voltage of 17.5V. They studied the effects of motor parameters and bubble parameters on TENG output performance. Integrating this TENG into a water level monitoring system can successfully monitor water level height (Li et al., 2022). Tao et al. used two-dimensional materials with excellent conductivity to fabricate a high-performance TENG and designed a unique multi-layer spring structure. Research shows that the output performance of this TENG is improved by 300% compared with simply using PVDF as a material. They also used the TENG to successfully collect the flow energy of drinking water and realize water level monitoring. This self-powered water level and water quality monitoring system based on TENG is of great significance to the optimization of traditional sensors (Tao et al., 2024). Xuan et al. designed a low-resistance rotating TENG using rabbit hair and FEP brushes and combined it with a memory alloy. Research results show that the TENG can still ensure output stability after 100,000 cycles of operation. They also designed a water temperature monitoring system (Xuan et al., 2023).
3.2 Wastewater pollutant treatment based on TENG
In agriculture, the use of pesticides and fertilizers often produces wastewater containing nitrogen, phosphorus, heavy metals, and other toxic substances. In some remote areas, the treatment of such wastewater has become a difficult task because it can easily contaminate drinking water sources and pose a serious threat to human life and health. TENG has shown significant advantages in wastewater monitoring and pollutant treatment due to its remark-able output characteristics and environmental friendliness.
Zhu et al. designed a flexible corrugated TENG to drive an electro-Fenton system for methyl blue degradation. The open-circuit voltage and short-circuit current of this system can reach 610V and 1.93 mA respectively, providing the electric Fenton system with powerful reaction power (Figure 1G). The results showed that the system’s degradation efficiency of methyl blue could reach 98% within 58 min, The degradation results are shown in Figure 1H. This new self-powered electrocatalytic system provides new ideas for the large-scale application of electro-Fenton (Zhu et al., 2021). Dong et al. designed a spherical TENG to increase the generation of free radicals during the electrocatalytic process (Figure 1I). They established a self-powered electrocatalytic system using the DC pulse output of the TENG. The results showed that the ATZ removal rate of this system increased by 8% within 30 min (Dong et al., 2022). Tian et al. designed a spiral spring-type TENG and established a self-powered Fenton system based on it to degrade organic pollutants. The output current of this TENG can reach 700 μA. The results show that the degradation efficiency of malachite green and methylene blue by this system can reach 98% within 80 min (Tian et al., 2021). Wang et al. synthesized a new type of ZnO nanorod array through a hydrothermal method. Using this material to manufacture TENG can greatly increase its output current density (Figure 1J). They used this system to degrade the wastewater pollutant rhodamine, and the results showed that the degradation efficiency was as high as 100%, and it also showed excellent reusability (Wang et al., 2022).
In many remote areas, it is difficult to establish a complete wastewater treatment system and there is not enough electricity supply. TENG can collect and utilize mechanical energy in the environment to realize a self-powered system, which provides a new development direction for wastewater purification in remote areas. Jeon et al. designed a TENG that can collect wind energy and built a self-powered electrocoagulation system based on it. Research results show that this system can effectively remove algae and organic pollutants in water. This system is easy to operate, has a simple structure and is small in scale. It is of extremely important significance for wastewater purification in remote areas (Jeon et al., 2016). In the process of wastewater purification, the most easily collected mechanical energy must be the mechanical energy of water flow. Zhou et al. designed a rotating TENG that can collect water flow energy and achieved efficient removal of hexavalent chromium through the pulse output of the TENG. This also proves the feasibility and effectiveness of self-powered electrochemistry to use harvested energy to clean environmental pollution (Zhou et al., 2019). Furthermore, Li et al. introduced a β-cyclodextrin-based TENG in 2015 (Li et al., 2015), which is capable of harnessing the water wave energy from wastewater and converting it into electricity for the degradation of phenol. The research showed that phenol was ultimately transformed into carbon dioxide and water molecules. Yu et al. proposed a TENG based on graphite microfibers to harvest wind energy and constructed a complete photoelectrocatalytic system (Yu et al., 2015). Similarly, Chen et al. designed a rotating TENG to harvest the mechanical energy from water flow (Chen et al., 2016). This system, connected to an electrode through a rectifier bridge, was used to create a sustainable wastewater treatment device. Experiments with rhodamine solution and copper ion solution demonstrated that the system could completely degrade the rhodamine solution within 15 min, while achieving a 97.3% degradation efficiency of the copper ion solution within 3 h. Moreover, Gao et al. designed a self-contained rotating TENG comprising a stator and a rotor (Gao et al., 2017). By incorporating a rectifier, they established an electrocatalytic system that effectively treated 4-aminoazobenzene. The results revealed that the pollutants were completely mineralized into carbon dioxide during the process.
On the other hand, piezoelectric nanogenerators (PENG) are based on the piezoelectric effect, where certain materials produce charge separation when subjected to external pressure or strain. At the nanoscale, this effect is used to generate electrical energy from pressure or vibration. Piezoelectric nanogenerators are often used for energy harvesting from environmental vibrations or mechanical vibrations. For example, they can be embedded in structures or devices and use surrounding vibrations to generate electrical energy for use in wireless sensors, smart structures, and other fields. PENG has also made great progress in research in the fields of environmental monitoring and pollutant treatment. Mishra et al. designed a piezoelectric catalytic fabric that eliminates the dependence on ultrasonic waves and greatly promotes the application of piezoelectric catalysis in the field of water treatment (Mishra et al., 2019). Tang et al. prepared piezoelectric materials with excellent performance and achieved efficient degradation of TC (Tang et al., 2022). Bagchi et al. prepared NaNbO3 powder through a hydrothermal method, which greatly improved the piezocatalytic efficiency (Bagchi et al., 2020). It is noted that TENG is well-suited for micro-devices and scenarios characterized by frequent frictional motion. On the other hand, PENG excels in vibration environments and demonstrates the capability to deliver relatively high energy density.
4 Discussion
Recently, TENG research in environmental engineering has proliferated and advanced rapidly. TENG’s environmental sustainability and cost-effectiveness offer significant advantages in environmental monitoring and pollutant treatment. Nevertheless, certain pivotal issues remain unresolved. In environmental monitoring, the long-term stability of TENG is of paramount importance. Furthermore, extended operation of equipment in challenging aquatic environments, a common requirement for water quality testing, places substantial demands on TENG durability. Additionally, ultra-high-precision parameter monitoring is occasionally required, necessitating enhanced sensitivity and accuracy from TENG. While TENG’s sensitivity offers significant benefits in responding to environmental parameter changes, it is susceptible to environmental interference. Consequently, developing TENG with robust anti-interference capabilities remains a critical challenge for advancing this technology.
Traditional environmental monitoring and waste treatment methods often face challenges in remote areas. TENG’s self-powering capability offers significant advantages in such locations. Implementing a self-powered wastewater monitoring and treatment system addresses the issue of limited power supply in remote regions. Furthermore, TENG is anticipated to find applications in diverse environmental monitoring areas, encompassing not only water quality but also air and soil quality, among other parameters. It can be integrated with compatible intelligent terminals to enable real-time monitoring and transmission of environmental data. Simultaneously, there is an expectation to deploy self-powered wastewater treatment systems utilizing TENG in these regions to harness mechanical energy from the environment for electrochemical pollutant treatment. The discovery of TENG introduces a fresh approach to sewage treatment in remote regions, aligning with the principles of environmental sustainability. TENG exhibits significant potential in wastewater treatment. As technology continues to advance, TENG is anticipated to assume an even more prominent role in wastewater treatment.
Author contributions
WQ: Investigation, Writing–original draft. CZ: Methodology, Writing–review and editing. PL: Conceptualization, Writing–review and editing. WS: Investigation, Writing–review and editing. LG: Conceptualization, Writing–review and editing. GS: Conceptualization, Writing–review and editing. RC: Supervision, Writing–review and editing.
Funding
This paper is supported by open funding of Qingdao Key Laboratory of Groundwater Resources Protection and Rehabilitation (DXSKF2022Y02) and Guangdong Province Education Department (Grant No. 2022KTSCX069).
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.
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Keywords: self-powered system, triboelectric nanogenerator, agricultural activities, environmental monitoring, wastewater treatment, environmental protection
Citation: Qu W, Zhong C, Luan P, Shi W, Geng L, Shi G and Chen R (2024) Self-powered system based on triboelectric nanogenerator in agricultural groundwater pollution monitoring and control. Front. Energy Res. 12:1324866. doi: 10.3389/fenrg.2024.1324866
Received: 20 October 2023; Accepted: 22 March 2024;
Published: 05 April 2024.
Edited by:
Awadesh Kumar Mallik, Nanyang Technological University, SingaporeReviewed by:
Pradip Thakur, Netaji Nagar College for Women, IndiaKalpataru Panda, Manipal Institute of Technology, India
Copyright © 2024 Qu, Zhong, Luan, Shi, Geng, Shi and Chen. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Gaofei Shi, Z2ZzaGkxMjNAMTI2LmNvbQ==