Tarik Della Santina Mohallem

Bravo Motor Company

Title: Enhancing Lithium Battery Performance through LiFeO2-C Inkjet Technology and Quantum Capacitance Increment in Ferromagnetic Cathodes

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Biography

Tarik Della Santina Mohallem, Brazilian physicist and computer engineer, founder of the largest nanotechnology company in Brazil and today CTO of a Li battery factory, endeavors to apply his accumulated experience in the field of applied nanotechnology, inkjet printing, highly concentrated ceramic dispersion, and energy storage devices to the generation of new nanomaterials and industrial techniques for the advance of effective and efficient storage solutions.

Abstract

Advancements in energy-storage technology have paved the way for more effective and efficient storage solutions. The development of new cathode materials for lithium batteries is a critical area of focus as they are widely used in electric vehicles and portable electronics. A new ferromagnetic LiFeO2-C combined with rGO-ferrocene battery cathode technology using inkjet ink process syntheses with quantum capacitance increment has gained attention.

LiFeO2-C and rGO-ferrocene are promising materials for battery development due to their high energy density, thermal stability, and large quantum capacitance. The combination of these materials aims to create a highly efficient, reliable, and high-energy-density active layer. The inkjet ink synthesis process allows precise control of the film composition, with benefits over traditional methods, such as creating complex geometries and high accuracy and precision.

Using alternating and direct magnetic fields in the final new battery can improve the performance, impact the crystal structure, and control the spike orientation for increased energy density, longer cycle life, and better charge/discharge efficiency. The development of this new cathode material has the potential to revitalize lithium batteries, leading to increased efficiency, reliability, and energy density, with a significant impact on the electric vehicle and stationary energy storage systems.

The new ferromagnetic LiFeO2-C combined with rGO-ferrocene battery cathode technology, quantum capacitance improvement, and inkjet technology is a promising direction in advance of energy storage technology. The combination of advanced materials and innovative processing methods has the potential to significantly improve the performance of lithium batteries and pave the way for new advanced energy storage devices.