NANOSYSTEMS
Innovative Magnetic Nanomaterials for Improved Energy Storage
Subhi Hammadi Hamdoun
Alnoor University, https://alnoor.edu.iq/
Nineveh 41012, Iraq
E-mail: sebhi.hamadi@alnoor.edu.iq
Salah Yehia Hussain
Al Mansour University College, https://muc.edu.iq/
Baghdad 10067, Iraq
E-mail: hussain@muc.edu.iq
Saadi Mohamed Dhahir Nuzal
Al Hikma University College, https://hiuc.edu.iq/
Baghdad 10015, Iraq
E-mail: saadidhaher@yahoo.com
Aqeel Mahmood Jawad
Al-Rafidain University College, https://ru-iq.com/
Baghdad 10064, Iraq
E-mail: aqeel.jawad@ruc.edu.iq
Ibraheem Nadher
Al-Turath University, https://uoturath.edu.iq/
Baghdad 10013, Iraq
E-mail: ibraheemnadher@uoturath.edu.iq
Received May 22, 2024, peer-reviewed May 27, 2024, accepted May 31, 2024, published September 17, 2024.
Abstract: Background: Finding effective energy storage technologies is crucial for transitioning to sustainable energy systems. Magnetic nanoparticles have emerged as options due to their distinctive magnetic characteristics, which can considerably improve the performance of energy storage systems. Objective: This research aims to investigate innovative magnetic nanoparticles and assess to increase the efficiency and capacity of energy storage systems. The emphasis is on developing materials with optimal magnetic characteristics and incorporating them into current energy storage methods. Methods: Co-precipitation and thermal breakdown were used to create a range of new magnetic nanomaterials. Vibrational sample magnetometry, X-ray diffraction, and cyclic voltammetry were used to determine these materials' magnetic characteristics, structural integrity, and electrochemical performance. Subsequent integration into supercapacitors and lithium-ion batteries was carried out to evaluate energy storage capacity. Results: The synthesized magnetic nanoparticles showed improved magnetic saturation and charge-discharge characteristics compared to standard materials. When used in supercapacitors, they increased capacitance by 20% and improved cycle stability by 25%. Similarly, these nanomaterials improved the energy density of lithium-ion batteries by 15% and increased their longevity by 30%. Conclusion: The unique magnetic nanoparticles created in this work significantly improve the performance of energy storage devices. The increased capacitance, energy density, and operational stability indicate that these materials for future energy storage applications. Further study is required to optimize these materials for commercial application and investigate their scalability and environmental effects.
Keywords: Magnetic Nanomaterials, Energy Storage, Supercapacitors, Lithium-ion Batteries (Li-ion), Electrochemical Performance, Synthesis Techniques, Charge-Discharge Capacity, Energy Density, Cycle Stability, Thermal Decomposition
UDC 620.9, 681.11, 66.086
RENSIT, 2024, 16(5):793-802e
DOI: 10.17725/j.rensit.2024.16.793
Full-text electronic version of this article - web site http://en.rensit.ru/vypuski/article/604/16(6)793-802e.pdf