applied in commercial electric and hybrid electric vehicles. However, the increasing market demand for rechargeable LIBs has increased the concerns regarding the economic sustainability of the LIB technology owing to uneven geographical distribution and relatively low amount of available lithium resources. [1-3] Thus, battery technologies based on abundant and inexpensive resources shall be an important option for large-scale energy storage devices. In this context, sodium-ion battery (SIB) technologies have emerged as a promising and low-cost alternative to LIBs. An intercalation-based chemical mechanism, similar to that of their LIB counterparts, wide sodium resource availability, and excellent electrochemical performance make SIBs an attractive candidate technology for large-scale storage devices. A variety of electrode materials such as layered oxides, polyanions, and fluorophosphates were successfully studied as cathodes for SIBs. [4,5] Although graphite does not offer a favorable Na + intercalation chemistry, several metal sulfides, metals, phosphides, alloys, and hard carbon were investigated as anodes for SIBs. [6-8] The limited capacity of metal oxides, poor cycle life, high cost of hard carbon, and large volume expansion of alloy/metal type anodes limit their practical application. [9,10] Transferring the experience gained from current LIBs to SIBs may lead to the rapid commercialization of the SIB technology. The most studied electrode materials in both LIBs and SIBs are based on transition metal-based chemistries using metal elements that are generally nonrenewable resources. Furthermore, the highly toxic nature of transition metals and high energy consumption involved in metal mining must be addressed to increase the sustainability and environment friendliness of energy storage devices. [11-13] Organic materials are promising candidates for further advancing the sustainability and ecofriendliness of energy storage devices. Organic electrode materials offer many advantages because they mostly consist of light elements such as C, H, O, N, and S. First, organic electrode materials are directly available from natural resources or can be prepared from natural derivatives. [14,15] Organic electrodes have good structural flexibility and wide chemical diversity; further, they can provide a high specific capacity and high voltage at low Sodium-ion batteries (SIBs) have become increasingly important as next-generation energy storage systems for application in large-scale energy storage. It is very crucial to develop an eco-friendly and green SIB technique with superior performance for sustainable future use. Replacing the conventional inorganic electrode materials with green and safe organic electrodes will be a promising approach. However, the poor electrochemical kinetics, unstable electrode-electrolyte interface, high solubility of the electrodes in the electrolyte, and large amount of conductive carbon present great challenges for organic SIBs. In this study, the issues of organic electrodes are addressed ...
