Industrial Consultancy & Sponsored Research (IC&SR) , IIT Madras
Asymmetric Supercapacitors and their Synthesis Thereof
Technology Category/ Market
Category – Energy Storage Devices and Nanofiber Technology
Applications – Advanced Materials , Electronic system & Design Manufacturing, Renewable energy storage, Aerospace applications, Power Backup systems
Industry –Energy Storage and Renewable Technologies
Market -The global energy storage systems market size was valued at US$ 210.92 billion in 2021 and is expected to hit US$ 435.32 billion by 2030 and poised to grow at a CAGR of 8.4% from 2022 to 2030.
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Problem Statement
- Current supercapacitors face limitations in performance due to poor electronic conductivity and low rate capability of MnO2, necessitating improved cathode materials.
- There is a need for high-conductive and high-aspect-ratio asymmetric supercapacitors with enhanced cathode materials, addressing the limitations of existing designs for practical applications.
Technology
Core-Shell Nanofiber Design:
- Introduces a novel core-shell structure where nanofibers of a second metal oxide (e.g., MnO2) are coated on a Nano fibrous first metal oxide (e.g., ZnO), optimizing energy storage capabilities
Electrospinning Technology:
- Utilizes electrospinning to create Nano fibrous mats, offering a high aspect ratio, large surface area, and ideal morphology for energy storage devices.
Hydrothermal Coating Process:
- Implements a hydrothermal coating method to apply Nano flakes of a second metal oxide onto the first metal oxide nanofibers, enhancing the overall performance of the super capacitor electrodes.
Calcination for Morphological Optimization:
- Involves controlled calcination at 500°C to optimize the granular morphologies of the metal oxide nanofibers, ensuring improved conductivity and efficient charge/discharge cycling.
Asymmetric Super capacitor Configuration:
- Integrates the synthesized core-shell nanofibers as the cathode, paired with a carbonaceous active material as the anode, resulting in an asymmetric super capacitor with high conductivity and aspect ratio.
Key Features/ Value Proposition
Technical Perspective:
- The invention enhances supercapacitor performance by introducing a core-shell nanofiber structure, addressing issues of poor electronic conductivity in MnO2 and achieving optimal electrode morphologies through controlled synthesis methods.
User Perspective:
- Users benefit from improved energy storage devices with higher efficiency and reliability, offering applications in portable electronics, electric vehicles, renewable energy, and aerospace, backed by a cost-effective and scalable synthesis process.
Questions about this Technology?
Contact for Licensing
sm-marketing@imail.iitm.ac.in
ipoffice2@iitm.ac.in
Research Lab
Prof. Srinivasan K
TDCE, Lab. Department of Mechanical Engineering
Dr. Abhijit Dhamanekar (Former PhD Student)
Research Associate, JNCASR Bangalore
Intellectual Property
- IITM IDF Ref. 1349
- IN 434937 (PATENT GRANTED)
Technology Readiness Level
TRL- 3/4
Proof and concept validated