Sustainable-inspired design of efficient organic electrodes for rechargeable sodium-ion batteries: Conversion of P-waste into E-wealth device

“…Finally, the precipitate is dried in a vacuum oven overnight at 110 °C and used as an organic linker. Also, the pristine TPA has been fabricated as an organic anode for lithium‐ion batteries in previous work [25,26] . Herein, Ce‐MOF is obtained by mixing an equimolar quantity of TPA (recycled from PET) solution with a saturated 1 mmol cerium chloride solution in DMF solvent.…”

“…It is used in various fields, such as luminescent adsorption, sensing, photocatalysts, and catalysis applications [23,24] . The derivative, cerium oxide (CeO 2 ), also possesses manifold disciplines such as oxygen‐energy storage, optical properties, diffusivity, and carbon dioxide capture [25] . However, no significant attention has been on lanthanide‐based MOF and their oxide in energy storage applications.…”

“…[23,24] The derivative, cerium oxide (CeO 2 ), also possesses manifold disciplines such as oxygen-energy storage, optical properties, diffusivity, and carbon dioxide capture. [25] However, no significant attention has been on lanthanidebased MOF and their oxide in energy storage applications. In addition, both Ce 3 + and Ce 4 + precursors can be used to synthesize a cerium-based MOF.…”

Spherically Structured Ce‐Metal‐Organic Frameworks with Rough Surfaces and Carbon‐Coated Cerium Oxide as Potential Electrodes for Lithium Storage and Supercapacitors

“…Finally, the precipitate is dried in a vacuum oven overnight at 110 °C and used as an organic linker. Also, the pristine TPA has been fabricated as an organic anode for lithium‐ion batteries in previous work [25,26] . Herein, Ce‐MOF is obtained by mixing an equimolar quantity of TPA (recycled from PET) solution with a saturated 1 mmol cerium chloride solution in DMF solvent.…”

“…It is used in various fields, such as luminescent adsorption, sensing, photocatalysts, and catalysis applications [23,24] . The derivative, cerium oxide (CeO 2 ), also possesses manifold disciplines such as oxygen‐energy storage, optical properties, diffusivity, and carbon dioxide capture [25] . However, no significant attention has been on lanthanide‐based MOF and their oxide in energy storage applications.…”

“…[23,24] The derivative, cerium oxide (CeO 2 ), also possesses manifold disciplines such as oxygen-energy storage, optical properties, diffusivity, and carbon dioxide capture. [25] However, no significant attention has been on lanthanidebased MOF and their oxide in energy storage applications. In addition, both Ce 3 + and Ce 4 + precursors can be used to synthesize a cerium-based MOF.…”

Spherically Structured Ce‐Metal‐Organic Frameworks with Rough Surfaces and Carbon‐Coated Cerium Oxide as Potential Electrodes for Lithium Storage and Supercapacitors

“…Among these, supercapacitors play an important role in hybrid, power grid, electric vehicles, and low-energy industrial equipment, etc. As a promising energy storage system, supercapacitors have attracted numerous [4]- [6]. Supercapacitors or ultracapacitors are electrical energy repository devices.…”

Biocarbon Derived from Seeds of Palmyra Palm Tree for a Supercapacitor Application

“…The use of terephthalate derivatives is an interesting alternative because it is rapid and easy to produce from the upcycling of PET at mild conditions. In a similar work, Na 2 TP was obtained from waste PET bottles by treating them with concentrated sulphuric acid at 120 °C for 6 h. 40 The terephthalic acid obtained was purified by precipitation in water prior to being treated with a solution of Na 2 CO 3 in ethanol for 12 h to finally obtain Na 2 TP. XRD analysis was performed to confirm the purity of the product and investigate the structure, while the electrochemical experiments on the electrode made of Na 2 TP revealed promising results.…”

From plastic waste to new materials for energy storage