Starch-Derived Hierarchical Porous Carbon with Controlled Porosity for High Performance Supercapacitors

Abstract: The development of green and clean synthetic techniques to produce carbon materials for energy storage and conversion applications has motivated researchers to use sustainable biomass. In this study, hierarchical porous carbon (HPC) with very high specific surface area and controlled porosity is synthesized by a novel and facile method, which employs an exothermic pyrolysis process of starch−magnesium nitrate raw materials with subsequent high temperature thermal treatment and acid washing. The biomass starch … Show more

“…Due to the increasing deterioration of environment and the urgent demand for clean and renewable energy, advanced energy storage technologies have gained considerable attention [1,2,3]. Among diverse energy storage systems, electrochemical capacitor, so-called supercapacitor, is recognized as one of the most promising next-generation candidates because of its ultrahigh power density, short charge/discharge time, long cycle life, stable performance, and broad working temperature, which has found many applications in consumer electronics, backup power supply, hybrid electrical vehicle, and implantable medical devices [3,4,5]. Based on the charge storage mechanism, supercapacitors can be classified as electrical double-layer capacitors (EDLCs) and pseudocapacitors [6,7].…”

“…Especially, porous carbon derived from natural substances stands out and becomes a hotspot in the field of supercapacitor, since its renewable precursor, abundant resources and easy fabrication process make it quite suitable for large-scale production and application [11,12,13,14,15,16,17]. For instance, some effective strategies, including one-step activation, template method as well as combination of carbonization and activation, have been proposed to synthesize porous carbon by adopting wheat straws, rice bran, almond shells, pig nails, plant leaves, corn, silk and starch as raw materials [5,11,12,13,14,15,16,17]. These biomass-derived porous carbon products feature substantial micropores (˂2 nm), resulting in large specific surface area and presenting high specific capacitance.…”

Hierarchical Porous Carbon Derived from Sichuan Pepper for High-Performance Symmetric Supercapacitor with Decent Rate Capability and Cycling Stability

“…Due to the increasing deterioration of environment and the urgent demand for clean and renewable energy, advanced energy storage technologies have gained considerable attention [1,2,3]. Among diverse energy storage systems, electrochemical capacitor, so-called supercapacitor, is recognized as one of the most promising next-generation candidates because of its ultrahigh power density, short charge/discharge time, long cycle life, stable performance, and broad working temperature, which has found many applications in consumer electronics, backup power supply, hybrid electrical vehicle, and implantable medical devices [3,4,5]. Based on the charge storage mechanism, supercapacitors can be classified as electrical double-layer capacitors (EDLCs) and pseudocapacitors [6,7].…”

“…Especially, porous carbon derived from natural substances stands out and becomes a hotspot in the field of supercapacitor, since its renewable precursor, abundant resources and easy fabrication process make it quite suitable for large-scale production and application [11,12,13,14,15,16,17]. For instance, some effective strategies, including one-step activation, template method as well as combination of carbonization and activation, have been proposed to synthesize porous carbon by adopting wheat straws, rice bran, almond shells, pig nails, plant leaves, corn, silk and starch as raw materials [5,11,12,13,14,15,16,17]. These biomass-derived porous carbon products feature substantial micropores (˂2 nm), resulting in large specific surface area and presenting high specific capacitance.…”

Hierarchical Porous Carbon Derived from Sichuan Pepper for High-Performance Symmetric Supercapacitor with Decent Rate Capability and Cycling Stability

“…In a Nyquist plot, typically, an ideal capacitor without diffusion resistance exhibits a vertical curve at the low frequency region, [36,37] so that the RGOÀ SnO 2 À NR electrode with the nearly steep profile indicates more ideal capacitive characteristic than the RGOÀ SnO 2 À NP and bare RGO electrodes, as displayed in Figure 6a. In a Nyquist plot, typically, an ideal capacitor without diffusion resistance exhibits a vertical curve at the low frequency region, [36,37] so that the RGOÀ SnO 2 À NR electrode with the nearly steep profile indicates more ideal capacitive characteristic than the RGOÀ SnO 2 À NP and bare RGO electrodes, as displayed in Figure 6a.…”

“…The reaction properties of the electrode surface were further analyzed through the electrochemical impedance spectroscopy (EIS) measurement, which is a powerful tool to investigate the frequency responsive behaviors. In a Nyquist plot, typically, an ideal capacitor without diffusion resistance exhibits a vertical curve at the low frequency region, [36,37] so that the RGOÀ SnO 2 À NR electrode with the nearly steep profile indicates more ideal capacitive characteristic than the RGOÀ SnO 2 À NP and bare RGO electrodes, as displayed in Figure 6a. Moreover, the magnified Nyquist plots of the three samples in the inset of Figure 6a clearly show the Warburg impedance indicating the transition domain with a slope of almost 45°in the medium frequency region (between the semicircle and steep linear curve), which is related to the mass transfer at the electrolyte/ electrode interface.…”

Improved Ion‐Transfer Behavior and Capacitive Energy Storage Characteristics of SnO₂ Nanospacer‐Incorporated Reduced Graphene Oxide Electrodes

“…The template method is a powerful tool to synthesize biomass-derived PC with tailored pore dimension and distribution. The involved hard and soft templates are both vital to the synthesis of PC materials with regulable pore dimension and surface area [82][83][84][85]. As for template method, the technology is grounded on the self-assemble of block copolymers, surfactants, organic compounds, and so forth [86,87].…”

Biomass-Derived Porous Carbon-Based Nanostructures for Microwave Absorption