Ragu Sasikumar, Byungki Kim, Young Sun Mok, Roshan Mangal Bhattarai
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We utilized finger-tapping and acoustic motions to generate the voltages from the nanogenerator and stored them in the supercapacitor device to power portable electronic devices. The piezoelectric performance showed that the nanogenerator can generate a peak-to-peak voltage of 2.81 V (~ 4.2 times better than pure molybdenum disulfide) due to the incorporation of terbium and molybdenum disulfide, which allows for flexible orientation of terbium–oxygen, tungsten–oxygen, and molybdenum–sulfur bonds under external force. The fabricated nanogenerator exhibited a power density of 7.3 µW m<sup>−2</sup>, which is higher than previously reported results. Next, electrochemical supercapacitor studies showed a higher capacity (62.6 mAh cm<sup>−2</sup>) for the proposed composite than that of molybdenum disulfide (58.8 mAh cm<sup>−2</sup>) and pure terbium tungstate (21.4 mAh cm<sup>−2</sup>). Finally, studies on self-charging power systems showed that it can self-charge to 1.6 V within 237 s and self-discharge very slowly at 11,763 s (~ 3.26 h) until 57 mV, powering various electronics and demonstrating its practicability. These excellent results of the piezoelectric-driven energy transfer process in self-charging power systems demonstrate its potential capability as a sustainable power source for portable electronic devices.</p></div>","PeriodicalId":7220,"journal":{"name":"Advanced Composites and Hybrid Materials","volume":"7 6","pages":""},"PeriodicalIF":23.2000,"publicationDate":"2024-10-23","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"“One-stone-two-birds”: engineering a 2D layered heterojunction of terbium tungstate incorporated on molybdenum disulfide nanosheets for a battery-free self-charging power system via the integration of a wearable piezoelectric nanogenerator and an asymmetric supercapacitor\",\"authors\":\"Ragu Sasikumar, Byungki Kim, Young Sun Mok, Roshan Mangal Bhattarai\",\"doi\":\"10.1007/s42114-024-01011-4\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>Piezoelectric-driven self-charging power systems play a crucial role nowadays, as they can simultaneously harvest, convert, store, and deliver energy to portable electronic devices. 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The fabricated nanogenerator exhibited a power density of 7.3 µW m<sup>−2</sup>, which is higher than previously reported results. Next, electrochemical supercapacitor studies showed a higher capacity (62.6 mAh cm<sup>−2</sup>) for the proposed composite than that of molybdenum disulfide (58.8 mAh cm<sup>−2</sup>) and pure terbium tungstate (21.4 mAh cm<sup>−2</sup>). Finally, studies on self-charging power systems showed that it can self-charge to 1.6 V within 237 s and self-discharge very slowly at 11,763 s (~ 3.26 h) until 57 mV, powering various electronics and demonstrating its practicability. 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引用次数: 0
摘要
压电驱动的自充电电源系统能够同时为便携式电子设备收集、转换、存储和输送能量,因此在当今发挥着至关重要的作用。研究人员专注于两大目标:(1) 了解利用可穿戴柔性压电纳米发电机从环境可持续来源收集能量的主要机制;(2) 改进能量存储和传输过程,如超级电容器。在此,我们开发了集成了压电纳米发电机和非对称超级电容器装置的自充电电源系统。我们利用手指敲击和声波运动从纳米发电机产生电压,并将其储存在超级电容器装置中,为便携式电子设备供电。压电性能表明,纳米发电机可产生 2.81 V 的峰-峰电压(约为纯二硫化钼的 4.2 倍),这是由于铽和二硫化钼的加入,使得铽-氧、钨-氧和钼-硫键在外力作用下可灵活取向。制造出的纳米发电机功率密度为 7.3 µW m-2,高于之前报道的结果。接着,电化学超级电容器研究表明,与二硫化钼(58.8 mAh cm-2)和纯钨酸铽(21.4 mAh cm-2)相比,所提出的复合材料具有更高的容量(62.6 mAh cm-2)。最后,对自充电电源系统的研究表明,它可以在 237 秒内自充电至 1.6 V,并在 11,763 秒(约 3.26 小时)内非常缓慢地自放电至 57 mV,为各种电子设备供电,证明了它的实用性。压电驱动能量转移过程在自充电电源系统中取得的这些优异成绩证明了其作为便携式电子设备可持续电源的潜在能力。
“One-stone-two-birds”: engineering a 2D layered heterojunction of terbium tungstate incorporated on molybdenum disulfide nanosheets for a battery-free self-charging power system via the integration of a wearable piezoelectric nanogenerator and an asymmetric supercapacitor
Piezoelectric-driven self-charging power systems play a crucial role nowadays, as they can simultaneously harvest, convert, store, and deliver energy to portable electronic devices. Researchers are focused on two major objectives: (1) understanding the primary mechanisms of energy harvest from environmentally sustainable sources using wearable flexible piezoelectric nanogenerators and (2) improving the energy storage and delivery processes, such as supercapacitors, respectively. Herein, we developed self-charging power systems integrated with a piezoelectric nanogenerator and an asymmetric supercapacitor device. We utilized finger-tapping and acoustic motions to generate the voltages from the nanogenerator and stored them in the supercapacitor device to power portable electronic devices. The piezoelectric performance showed that the nanogenerator can generate a peak-to-peak voltage of 2.81 V (~ 4.2 times better than pure molybdenum disulfide) due to the incorporation of terbium and molybdenum disulfide, which allows for flexible orientation of terbium–oxygen, tungsten–oxygen, and molybdenum–sulfur bonds under external force. The fabricated nanogenerator exhibited a power density of 7.3 µW m−2, which is higher than previously reported results. Next, electrochemical supercapacitor studies showed a higher capacity (62.6 mAh cm−2) for the proposed composite than that of molybdenum disulfide (58.8 mAh cm−2) and pure terbium tungstate (21.4 mAh cm−2). Finally, studies on self-charging power systems showed that it can self-charge to 1.6 V within 237 s and self-discharge very slowly at 11,763 s (~ 3.26 h) until 57 mV, powering various electronics and demonstrating its practicability. These excellent results of the piezoelectric-driven energy transfer process in self-charging power systems demonstrate its potential capability as a sustainable power source for portable electronic devices.
期刊介绍:
Advanced Composites and Hybrid Materials is a leading international journal that promotes interdisciplinary collaboration among materials scientists, engineers, chemists, biologists, and physicists working on composites, including nanocomposites. Our aim is to facilitate rapid scientific communication in this field.
The journal publishes high-quality research on various aspects of composite materials, including materials design, surface and interface science/engineering, manufacturing, structure control, property design, device fabrication, and other applications. We also welcome simulation and modeling studies that are relevant to composites. Additionally, papers focusing on the relationship between fillers and the matrix are of particular interest.
Our scope includes polymer, metal, and ceramic matrices, with a special emphasis on reviews and meta-analyses related to materials selection. We cover a wide range of topics, including transport properties, strategies for controlling interfaces and composition distribution, bottom-up assembly of nanocomposites, highly porous and high-density composites, electronic structure design, materials synergisms, and thermoelectric materials.
Advanced Composites and Hybrid Materials follows a rigorous single-blind peer-review process to ensure the quality and integrity of the published work.