Mukesh Ganchi
- Assistant Professor Mechanical Department, Geetanjali Institute of Technical Studies, Udaipur Rajasthan India
Abstract
The integration of smart materials into mechanical systems for energy harvesting and storage marks a transformative leap in sustainable energy technology. These materials, responsive to environmental cues, offer innovative solutions for capturing energy from mechanical sources. Leveraging properties like piezoelectricity and thermoelectricity, smart materials efficiently convert mechanical energy into electrical energy, enabling devices to generate power from human motion or industrial machinery. Moreover, they enhance energy storage capacity and efficiency in batteries and capacitors, while their dynamic nature enables the creation of self-regulating systems adaptable to changing energy demands and environmental conditions. Despite their promise, challenges such as scalability and manufacturing costs require addressing to fully realize their potential in mechanical energy systems.
Keywords: Smart materials, Energy harvesting, Energy storage, Mechanical systems, Renewable energy, Sustainability.
[This article belongs to International Journal of Energy and Thermal Applications(ijeta)]
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References
- Armand, M., & Tarascon, J. M. (2008). Building better batteries. Nature, 451(7179), 652-657.
- Cheng, S., Wang, J., Sun, L., & Jiang, S. P. (2020). Challenges and opportunities of triboelectric nanogenerators for energy harvesting and sensing. Nano Energy, 70, 104461.
- Dunn, B., Kamath, H., & Tarascon, J. M. (2011). Electrical energy storage for the grid: A battery of choices. Science, 334(6058), 928-935.
- Gupta, R. K., & Kumar, R. (2019). Shape memory alloys: A state of art review. Materials Today: Proceedings, 18, 751-758.
- Mai, L., Xu, L., Han, C., Xu, X., Luo, Y., Zhao, S., & Liu, H. (2021). A comprehensive review of smart materials: Advances, challenges, and applications. Smart Materials in Medicine, 2, 1-24.
- Simon, P., Gogotsi, Y., & Dunn, B. (2014). Where do batteries end and supercapacitors begin? Science, 343(6176), 1210-1211.
- Wang, Z. L. (2013). Triboelectric nanogenerators as new energy technology for self-powered systems and as active mechanical and chemical sensors. ACS nano, 7(11), 9533-9557.
- Wang, Z. L., Chen, J., & Lin, L. (2012). Progress in triboelectric nanogenerators as a new energy technology and self-powered sensors. Energy & Environmental Science, 5(7), 8384-8393.
- Yu, A., Lu, G. Q., & Liu, J. (2016). Recent advances in energy materials by exploiting nanotechnology. Nano Today, 11(5), 718-758.
- Zhang, L., Zhao, C., Liu, Y., Wu, H., & Wu, G. (2020). Recent advances in triboelectric nanogenerator based on 2D materials. Nano Energy, 77, 105136.
- Gao, C., Kou, H., Peng, Q., Tan, C., Zhu, S., & Zhang, H. (2021). Smart hydrogel-based energy storage devices: Progress, challenges, and perspectives. Advanced Materials, 33(17), 2003757.
- Liu, Z., Su, J., Zhu, M., Li, H., & Liu, Z. (2020). Review on smart materials and structures for energy harvesting applications. Materials Research Express, 7(12), 122002.
- Kim, S., Yoo, D., Kim, H., Lee, S., Jeon, J., Han, J., & Kim, J. (2019). Recent advances in smart energy storage materials for self-healing, flexible, and transparent energy conversion and storage devices. Advanced Materials, 31(47), 1902007.
- Niu, S., Wang, X., Yi, F., Zhou, Y. S., Wang, Z. L., & Yang, R. (2015). Theory of freestanding triboelectric-layer-based nanogenerators. Nano Energy, 12, 760-774.
- Sun, N., Du, H., Wang, X., Zhang, Q., & Liu, Y. (2020). Triboelectric nanogenerator for energy harvesting from water wave: Progress and challenges. Nano Energy, 78, 105268.
- Zou, Y., Tan, P., Li, Z., Zhang, X., & Wong, C. P. (2021). A comprehensive review on 3D printing for triboelectric nanogenerators. Nano Energy, 83, 105785.
- Chen, X., Peng, L., Xie, Y., & An, Z. (2017). Solution-processed two-dimensional MoS2 nanosheets: preparation, hybridization, and applications. Angewandte Chemie International Edition, 56(5), 1190-1218.
- Bao, C., Liu, Z., & Zhu, H. (2019). Review of applications for flexible triboelectric nanogenerators. Nano-Micro Letters, 11(1), 17.
- Xu, Y., Zhang, L., Wang, Z. L., & Wang, S. (2015). Multi-layered structure design for high performance triboelectric nanogenerator. Nano Energy, 12, 626-633.
- Wang, X., Wang, S., Yang, Y., Wu, J., Guo, J., & Liu, Z. (2019). Self‐powered gas sensors based on the coupling effect of triboelectricity and surface oxygen adsorption. Advanced Materials, 31(19), 1807771.
Volume | 02 |
Issue | 01 |
Received | June 21, 2024 |
Accepted | June 24, 2024 |
Published | July 15, 2024 |
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