Advantage of Dimethyl Sulfoxide in the Fabrication of Binder-Free Layered Double Hydroxides Electrodes: Impacts of Physical Parameters on the Crystalline Domain and Electrochemical Performance

The electrode fabrication stage is a crucial step in the design of supercapacitors. The latter involves the binder generally for adhesive purposes. The binder is electrochemically dormant and has weak interactions, leading to isolating the active material and conductive additive and then compromising the electrochemical performance. Designing binder-free electrodes is a practical way to improve the electrochemical performance of supercapacitors. However, most of the methods developed for the fabrication of binder-free LDH electrodes do not accommodate LDH materials prepared via the co-precipitation or ions exchange routes. Herein, we developed a novel method to fabricate binder-free LDH electrodes which accommodates LDH materials from other synthesis routes. The induced impacts of various physical parameters such as the temperature and time applied during the fabrication process on the crystalline domain and electrochemical performances of all the binder-free LDH electrodes were studied. The electrochemical analysis showed that the electrode prepared at 200 degrees C-1 h exhibited the best electrochemical performance compared to its counterparts. A specific capacitance of 3050.95 Fg(-1) at 10 mVs(-1) was achieved by it, while its Rct value was 0.68 ohm. Moreover, it retained 97% of capacitance after 5000 cycles at 120 mVs(-1). The XRD and FTIR studies demonstrated that its excellent electrochemical performance was due to its crystalline domain which had held an important amount of water than other electrodes. The as-developed method proved to be reliable and advantageous due to its simplicity and cost-effectiveness.

Automated summary

The electrode fabrication stage is crucial in supercapacitor design, and designing binder-free electrodes is an effective way to improve electrochemical performance. This study developed a novel method to fabricate binder-free electrodes that can accommodate LDH materials from various synthesis routes. The impact of physical parameters on the crystalline domain and electrochemical performance of the electrodes was investigated.