MXene-Based Nanocomposites for Piezoelectric and Triboelectric Energy Harvesting Applications

Pabba, Durga Prasad; Satthiyaraju, Mani; Ramasdoss, Ananthakumar; Sakthivel, Pandurengan; Chidhambaram, Natarajan; Dhanabalan, Shanmugasundar; Abarzúa, Carolina Venegas; Morel, Mauricio J.; Udayabhaskar, Rednam; Mangalaraja, Ramalinga Viswanathan; Aepuru, Radhamanohar; Kamaraj, Sathish-Kumar; Murugesan, Praveen Kumar; Thirumurugan, Arun

doi:10.3390/mi14061273

Cited by 10 publications

(5 citation statements)

References 261 publications

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“…It is important to acknowledge that the presented results align with those of other nanocomposites. It should be noted that the tests were conducted under relatively low-force conditions [ 59 ]. For a comprehensive evaluation, the generated power was juxtaposed with that of other nanocomposites and MEMS devices, as illustrated in Table 6 .…”

Section: Resultsmentioning

confidence: 99%

Piezotronic Antimony Sulphoiodide/Polyvinylidene Composite for Strain-Sensing and Energy-Harvesting Applications

Jała,

Nowacki,

Toroń

2023

Sensors

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This study investigates the piezoelectric and piezotronic properties of a novel composite material comprising polyvinylidene fluoride (PVDF) and antimony sulphoiodide (SbSI) nanowires. The material preparation method is detailed, showcasing its simplicity and reproducibility. The material’s electrical resistivity, piezoelectric response, and energy-harvesting capabilities are systematically analyzed under various deflection conditions and excitation frequencies. The piezoelectric response is characterized by the generation of charge carriers in the material due to mechanical strain, resulting in voltage output. The fundamental phenomena of charge generation, along with their influence on the material’s resistivity, are proposed. Dynamic strain testing reveals the composite’s potential as a piezoelectric nanogenerator (PENG), converting mechanical energy into electrical energy. Comparative analyses highlight the composite’s power density advantages, thereby demonstrating its potential for energy-harvesting applications. This research provides insights into the interplay between piezoelectric and piezotronic phenomena in nanocomposites and their applicability in energy-harvesting devices.

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Section: Resultsmentioning

confidence: 99%

Piezotronic Antimony Sulphoiodide/Polyvinylidene Composite for Strain-Sensing and Energy-Harvesting Applications

Jała,

Nowacki,

Toroń

2023

Sensors

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“…MXene-based wearable devices typically require electrical connections with other components such as sensors, inter-connects, or power sources. 19,57 Ensuring reliable electrical connections between MXene and these components can be challenging due to the differences in material properties, contact resistance, or compatibility with soldering or bonding techniques. Thus, the achievement of low-resistance and stable electrical connections is essential for optimal device functionality.…”

Section: Mxenes In Wearable Electronicsmentioning

confidence: 99%

Advancements in MXene-based composites for electronic skins

Iravani,

Rabiee,

Makvandi

2024

J. Mater. Chem. B

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“…Examples include the development of a triboelectric nanogenerator for self-powered chemical sensors [251], the construction of a ring-shaped vibration TENG for vibration sensors [252], the creation of a sliding-mode TENG for self-powered security applications [253], the fabrication of a 3DWE-TENG for self-powered stretchable sensors, the construction of an SWF-TENG for self-powered stretchable sensing [254], the development of self-powered humidity sensors with structured surfaces (nanowire, nanoporous, nanotube, and monolayer) [255], the use of a garment-integrated TENG for pressure sensors [256], the construction of hybrid TENGs for self-powered sensors [257], self-powered humidity, and temperature sensors [258], the utilization of a flexible TENG based on MXene/GO composites for self-powered health monitoring [259], the construction of a C-TENG for self-powered strain sensors [260], and the production of a hybrid TENG and a piezoelectric nanogenerator for self-powered wear-able sensors [261]. Numerous surveys have highlighted the advantages of TENGs, such as their potential as a blue energy source [262], their role as a renewable energy resource [263], their green energy source suitability with sustainable diagnostics for human healthcare applications [244], their clean energy source attributes with small sizes [150], their ability to offer flexibility and smart applications through materials like MXene-TENG [264], their use as a self-powered device for biomechanical energy harvesting and behavior sensing [265], their suitability for portable and flexible wearable sensing and human healthcare applications [266], their ability to provide flexible and self-charging power systems [267], their capacity for stability and selectivity in self-powered and advanced chemical sensor systems [268], their capability to enhance the energy conversion efficiency for powering LEDs and various TENG applications [269], their proficiency as an effective power resource for flexible pressure sensing and portable electronic equipment [270], their competence in harvesting energy from low-frequency acoustic waves for capacitor charging [146], their ability to sensitively detect physiological signals [146], their characteristics of sustainable and efficient energy conversion ...…”

Section: Benefits Challenges and Solutionsmentioning

confidence: 99%

Advances in Triboelectric Nanogenerators for Sustainable and Renewable Energy: Working Mechanism, Tribo-Surface Structure, Energy Storage-Collection System, and Applications

Trinh,

Chung

2023

Processes

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Triboelectric nanogenerators (TENGs) are emerging as a form of sustainable and renewable technology for harvesting wasted mechanical energy in nature, such as motion, waves, wind, and vibrations. TENG devices generate electricity through the cyclic working principle of contact and separation of tribo-material couples. This technology is used in outstanding applications in energy generation, human care, medicinal, biomedical, and industrial applications. TENG devices can be applied in many practical applications, such as portable power, self-powered sensors, electronics, and electric consumption devices. With TENG energy technologies, significant energy issues can be reduced or even solved in the near future, such as reducing gas emissions, increasing environmental protection, and improving human health. The performance of TENGs can be enhanced by utilizing materials with a significant contrast in their triboelectrical characteristics or by implementing advanced structural designs. This review comprehensively examines the recent advancements in TENG technologies for harnessing mechanical waste energy sources, with a primary focus on their sustainability and renewable energy attributes. It also delves into topics such as optimizing tribo-surface structures to enhance output performance, implementing energy storage systems to ensure stable operation and prolonged usage, exploring energy collection systems for efficient management of harvested energy, and highlighting practical applications of TENG in various contexts. The results indicate that TENG technologies have the potential to be widely applied in sustainable energy generation, renewable energy, industry, and human care in the near future.

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MXene-Based Nanocomposites for Piezoelectric and Triboelectric Energy Harvesting Applications

Cited by 10 publications

References 261 publications

Piezotronic Antimony Sulphoiodide/Polyvinylidene Composite for Strain-Sensing and Energy-Harvesting Applications

Piezotronic Antimony Sulphoiodide/Polyvinylidene Composite for Strain-Sensing and Energy-Harvesting Applications

Advancements in MXene-based composites for electronic skins

Advances in Triboelectric Nanogenerators for Sustainable and Renewable Energy: Working Mechanism, Tribo-Surface Structure, Energy Storage-Collection System, and Applications

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