Hence, many researches have been focused on the development of novel electrode materials for high-performance supercapacitors.
Present article describes the development of novel electrode for the electrochemical detection of fluoride ion (F−) present in water.
Development of novel electrode materials with high energy and power densities for lithium-ion batteries (LIBs) is the key to meet the demands of electric vehicles.
Development of novel electrode materials with unique architectural designs is necessary to attain high power and energy density lithium-ion batteries (LIBs).
The development of novel electrode materials for electrochemical capacitors requires innovative approaches with an imperative to produce highly active materials while holding to simple and scalable synthetic approaches.
Rather, in the laboratory scale research, the progress in battery technology most times is primarily inclined toward the development of novel electrode active materials [6, 7, 8], followed by binders, electrolytes, and enhancement additives [9, 10, 11, 12, 13].
However, despite over 40 years of clinical practice and the development of novel electrode designs and treatment protocols, increases in clinical success, defined as the proportion of patients that experience 50% or greater self-reported pain relief, have stalled.
In summary, we have shown the effectiveness of the physical PLD method to decorate straightforwardly MWCNTs with Co Ni NPs for the development of novel counter electrodes for DSSC applications.
The present study opens-up the successful development of novel carbonaceous electrode with helical nanostructure for application particularly in SCs.
Because of the highly tunable properties of LbL assembled electrodes coupled with electrocatalytic NPs, we anticipate that the general concept presented here will offer new insights in the nanoscale control over the architecture of the electrode toward development of novel electroactive catalysts.
