Researchers have created a sophisticated binder for silicon oxide electrodes in lithium-ion batteries, improving their electrochemical efficiency and lifespan.
Lithium-ion batteries are widely used in various applications but need improved binders to enhance their performance to meet evolving demands. This is because silicon oxide (SiO), a promising anode material due to its high capacity and low cost, faces several challenges. These include poor conductivity, which leads to slower charging rates, and significant expansion during charging. Effective binders are thus essential to address these issues and ensure enhanced performance and prolonged durability for lithium-ion battery systems.
In a recent study published in the journal ACS Applied Energy Materials on February 8, 2024, Professor Noriyoshi Matsumi from the Japan Advanced Institute of Science and Technology (JAIST), along with doctoral student Noriyuki Takamori, former Senior Lecturer Rajashekar Badam, Dr. Tejkiran Pindi Jayakumar (former student), and researchers from Maruzen Petrochemical Company Ltd., have utilized poly(vinylphosphonic acid) (PVPA) as a binder for a micro-SiO electrodes, achieving superior performance compared to conventional cells.
Superior Performance of PVPA
According to Prof. Matsumi, “The PVPA binder should prove to be very useful in extending the life of high-performing lithium-ion secondary batteries. Particularly in the application of electric vehicles, there has been intense interest in enabling long life for lithium-ion secondary batteries. The use of PVPA will offer improved alternatives to commercially available binders, such as poly(acrylic acid) (PAA) and poly(vinylidene fluoride) (PVDF), etc.”
The study involved fabricating electrodes containing PVPA, PAA, and PVDF as binders, and their performance was assessed through electrochemical experiments and density functional theory. PVPA demonstrated notably stronger adhesion (3.44 N/m) to a copper support compared to conventional PAA (2.03 N/m), leading to significantly enhanced durability in lithium-ion batteries.
The PVPA-based cell also delivered almost twice the discharging capacity compared to the PAA-based cell after 200 cycles, with the PVPA-based half-cell achieving 1300 mAhg-1SiO after the same cycle count. Even after 200 cycles of charge-discharge, exfoliation from the current collector was not observed in scanning electron microscopy, unlike with PVDF or PAA binders. Furthermore, the stronger adhesion of PVPA helps stabilize the SiO-based anode, preventing its exfoliation even with significant volume expansion.
Collaboration and Patenting
Additionally, Maruzen Petrochemical Company Ltd., whose researchers were part of the study, has established an industrial production process for PVPA. Continuous collaboration between JAIST and Maruzen Petrochemical Company Ltd., along with the inclusion of additional battery production expertise from the company, may further accelerate the process toward real-life applications. Patents for this technology have been submitted both domestically (Japan) and internationally as a joint application by JAIST and Maruzen Petrochemical Company Ltd.
“An industrially feasible, high-performing binder like this will aid in the development of technology for highly durable and high-energy-density batteries. This will result in the wider adoption of EVs worldwide without concerns about performance degradation over a longer period. These materials can also be applicable to a variety of electric vehicles such as trains, ships, aircraft, etc., in the future,” envisions Prof. Matsumi.
In summary, scientists have developed a functional binder using poly(vinylphosphonic acid) for SiO-based anodes in lithium-ion batteries. This low-cost binder enhances performance compared to conventional options and represents a novel advancement for micro-SiO-based applications in electric vehicles and beyond!
Reference: “Facile Stabilization of Microsilicon Oxide Based Li-Ion Battery Anode Using Poly(vinylphosphonic acid)” by Noriyuki Takamori, Tadashi Yamazaki, Takuro Furukawa, Tejkiran Pindi Jayakumar, Rajashekar Badam and Noriyoshi Matsumi, 8 February 2024, ACS Applied Energy Materials.
DOI: 10.1021/acsaem.3c02127
This work was supported by JST SPRING, Grant Number JPMJSP2102.
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