Innovative approaches of porous carbon materials derived from energy waste and their electrochemical properties
0 Abstract
The pathway to sustainable development and carbon neutrality is contingent upon the development of high-performance porous carbon electrode materials sourced from biomass and industrial waste. The present research introduces an innovative approach for the fabrication of porous carbon, harnessing the collaborative impact of various materials to transform biomass in the form of corncobs and industrial byproduct fly ash into tiered porous carbon characterized by a high specific surface area and excellent functionality, via a simple hydrothermal activation method. This material is particularly well-suited for applications in supercapacitors, lithium-ion batteries, and other energy storage systems. The porous carbon material fabricated from these two waste streams boasts a wealth of pores and an exceptional specific surface area (1,768 m2 g-1), which in turn confers superior electrochemical performance. The material achieves a remarkable specific capacitance of up to 240 F g-1
Keywords
INTRODUCTION
Global warming is a result of climate change driven by human energy consumption and the release of significant carbon dioxide emissions, adversely affecting lives and leading to mounting issues. In 2020, China introduced its goals of carbon peaking and neutrality at the UN General Assembly. Subsequently, the nation outlined five key strategies, which include enhancing energy efficiency and establishing a green, low-carbon circular economy. Many fossil fuels are not fully converted during use, leaving byproducts rich in unburned carbon that can harm the environment. Thus, the path to carbon neutrality involves repurposing energy waste into advanced energy storage components for sustainable energy cycles[1-3].
Supercapacitors (SCs) are energy storage devices that operate on the principle of electrochemical conversion, offering quick charge-discharge capabilities, high power density, and long cycle life[4-10]. They are categorized into electric double-layer capacitors (EDLCs) and pseudocapacitors based on their storage mechanisms[11-13]. In EDLCs, the charging and discharging processes involve the complete adsorption and desorption of charges. The electrode materials used in EDLCs are primarily carbon materials with large surface areas, such as activated carbon (AC), hierarchically porous carbon (HPC), carbon nanotubes (CNT), graphene (GH), etc.[14-18]. The pore structures of these materials can be classified as micropores (less than
Biomass materials, with advantages such as being environment-friendly, sustainable, rich in heteroatoms, and cost-effective, have become the preferred choice for preparing EDLC electrode materials in recent years[23-26]. So far, a large amount of plant- or animal-derived biomass materials have been used to produce electrode materials for SCs with excellent electrochemical properties[26-28]. Ghosh et al. prepared AC from banana stem, corncob (CC) and potato starch by KOH activation or simple carbonization, in which the specific capacitance of KHC was about 225 F g-1 at 5 A g-1. In addition, they assembled KHC as a SC; after
CC, a lignocellulosic byproduct of corn threshing and refinement, is rich in cellulose, hemicellulose, and lignin, endowing it with desirable mechanical properties such as superior tensile strength, enhanced hygroscopicity, and exceptional abrasion resistance. As a biomass residue, CC has found applications across various industries, including abrasive polishing, desiccant materials, and nutritional feed additives, which positions it as a promising precursor for the large-scale synthesis of carbonaceous substrates[32]. Moreover, the intrinsic carbohydrate and crude protein content within CC offers the potential for in situ heteroatom doping, specifically nitrogen and oxygen, within the carbon matrix. Fly ash (FA), a particulate byproduct of fossil fuel combustion, is composed primarily of inorganic oxides such as SiO2, Al2O3, Fe2O3, and CaO, along with a residual carbon content[33,34]. The fine particle size and smooth surface texture of FA necessitate its responsible management to prevent environmental contamination. Although FA has been repurposed in various applications, ranging from cementitious materials to agronomic fertilizers, as well as in wastewater treatment and industrial recycling, its potential in the synthesis of electrode materials for energy storage devices such as SCs is a rapidly emerging field of interest[35].
In light of the above considerations and with a commitment to eco-friendly materials science, we have crafted an advanced strategy for the two-step hybrid conversion of materials. This process involves hydrothermal carbonization followed by activation to fabricate N/O co-doped, porous biomass-derived carbon. The hydrothermal carbonization phase promotes the selective decomposition of lignin and hemicellulose, thereby enhancing the mesoporosity and oxygenation of the carbon framework, which are crucial for improving electrochemical performance, particularly specific capacitance. This innovative strategy not only leverages the synergistic integration of these two waste streams but also introduces a groundbreaking method for fabricating advanced electrode materials for energy storage applications, highlighting the potential for valorizing industrial byproducts. The porous carbons derived from CC and FA, designated as CFCs, boast a 3D macroporous framework combined with microporous and mesoporous structures. They exhibit a high specific surface area of 1,768 m2 g-1, which marks an enhancement factor exceeding 70, thereby significantly amplifying the void fraction of the material. The specific capacitance of the sample in 6 M KOH electrolyte, measured using a three-electrode system, was as high as 240 F g-1 (at
EXPERIMENTAL
Material
The CC with a size of about 20 mesh is purchased from a food processing plant in Jiangsu province, China. FA with a size of about 300 mesh is purchased from an environmental protection company Henan province, China. Highly conductive graphene (HCG) and single-wall CNTs (SWNs) are purchased from Angxing New Carbon Materials Changzhou Co., Ltd., China. Polyvinyl pyrrolidone (The average molecular weight is 58000, K30 PVP), acetonitrile (ACS, ≥ 99.5% CH3CN), hydrochloric acid (AR, 36%-38% HCl), ethyl alcohol (AR, 99.7% C2H5OH), and potassium hydroxide (AR, 90% KOH) are purchased from Sinopharm Chem. Reagent Co., Ltd., China.
Preparation of porous carbons
CC and FA are mixed in a 1:2 ratio and then ball-milled for 12 h to get a fine mixture. A portion of 3 g of this mixture is dispersed in 20 mL 3 M HCl and then transferred to the inner tank of the hydrothermal kettle. After sealing the hydrothermal kettle, it is placed in an oven, and the temperature is raised to 200 °C for 2 h. The hydrothermal product is washed with deionized water until neutral, filtrated, and dried. The product is then soaked in 10 mL 6 M KOH for 12 h and subsequently transferred to an oven at 80 °C to evaporate any remaining liquid. Finally, the mixture is placed in a tube furnace protected by nitrogen atmosphere for carbonization. The temperature is increased to 700 °C at a rate of 2 °C s-1 and held for 3 h. After the furnace cools to room temperature, the sample is taken out, washed with 1 M HCl and dried in an oven at 80 °C overnight. The resulting product is named CFC; in addition, samples containing only CC or FA are prepared using the same method, named CC and FAC, respectively.
Preparation of self-supporting electrodes
Due to the complex preparation process of the electrode and the tendency for active material to detach from the substrate during long-term immersion in the electrolyte in a three-electrode test, we propose a method to fabricate self-supporting electrodes: CFCs, HCG, SWNs and PVP are added to acetonitrile with a ratio of 5:4:1:2, stirred for 2 h and then dispersed evenly with an ultrasonic cell crusher. The mixture is then filtered to form a film. This self-supporting has good conductivity, strength and toughness, making it suitable for a variety of test systems.
Characterization
This study uses Scanning Electron Microscopy (SEM, Hitachi S-4800) and Transmission Electron Microscopy (TEM, Fei Tecnai G2 F30) for the microstructural characterization of the sample materials. Chemical state and elemental composition analysis of the samples is conducted using X-ray Photoelectron Spectroscopy (XPS) on an Axis Ultra DLD (Kratos) spectrometer equipped with a monochromatic Al-Kα X-ray source. X-ray Fluorescence (XRF, Axios wavelength dispersive XRF spectrometer) is utilized to analyze the composition of FA qualitatively and quantitatively. The specific surface area and pore size distribution of the samples are measured using a nitrogen adsorption and desorption apparatus (Micromeritics ASAP 2020, USA) and are calculated according to the Brunauer-Emmett-Teller (BET) theory. Additionally, the mesopore volume and radius are determined using the Berret-Joyner-Halenda (BJH) method.
Electrochemical measurements
The electrochemical properties of the samples are evaluated using the CHI660D electrochemical workstation (Shanghaichenhua, China). Techniques including Cyclic Voltammetry (CV), Chronopotentiometry (CP), Electrochemical Impedance Spectroscopy (EIS), and cycle stability tests are performed within a conventional three-electrode configuration, utilizing a 50 mL 6 M KOH electrolyte solution. The working electrode consists of the prepared self-supporting electrodes; the counter electrode is a platinum (Pt) foil (2 × 2 cm2), and the reference electrode is a Hg/Hg2O electrode. CV measurements are conducted within a voltage range of -1.3 to 0.6 V, with scan rates varying from 0.01 to
The gravimetric specific capacitance (Cs, F g-1) of the prepared samples is computed from the discharge curve in accordance with[36-38]:
Herein, I represents the current (A), t is the discharge time (s), ΔV is the discharge voltage range (V), and m is the mass of the active material on the working electrodes (g).
The energy density (Ed) and the power density (Pd) of SC electrodes can be respectively calculated based on [39-41]:
where I is the current (A), m is the mass of the active material on the working electrodes (kg),
Preparation of lithium-ion battery
In this research, the CR2032 button battery case is employed to assemble the lithium-ion battery, with the process accomplished in an atmosphere-protected glove box. First of all, place the prepared self-supporting electrode on the positive electrode shell, and then put the polypropylene (PP) diaphragm and drop the appropriate electrolyte on it to moisten it. Next, position the lithium sheet at the center of the PP diaphragm, then place the nickel foam on the lithium sheet and drop the appropriate electrolyte, and subsequently cover the negative shell. Finally, the device is encapsulated under pressure. The EIS and CV of the battery are tested by Zhner Electrochemical Workstation (Hong Kong Global, China), and in addition, the charge and discharge, rate performance and cycle performance are tested by the Xinwell TC53 battery test system.
RESULTS AND DISCUSSION
Figure 1 shows a schematic diagram depicting the preparation of CFC. Low-cost CC and industrial waste FA are used as a self-template and template, respectively. The precursors are obtained by hydrothermal reaction to remove the existing metal oxides and retain the microporous structure. Then, the microporous and mesoporous structures are realized by high temperature carbonization and activation of KOH under N2 atmosphere.
Figure 1. A schematic illustration of CFC preparation by CC and FA.
Figure 2 shows the surface morphology of CC and FA before and after treatment respectively. As depicted in Figure 2A, untreated CC exhibits a substantial volume characterized by numerous large pores on its surface, approximately 25 μm in diameter. As can be further observed from the illustration, its surface is smooth with almost no pore structure. After being treated with hydrothermal and KOH activation [Figure 2B], the original pores on the CC surface disappear and are replaced by large pores. Through careful observation, it can be found that the size of these pores is similar to that of the original pores. It acts as a support and frame for the material. In addition, it can also be observed from the illustration that the surface of the CC at this time is still smooth, and there is only a large hole structure. Figure 2C shows FA without any treatment where it is clearly observed to consist of many balls and lumps of varying sizes. In order to explore its main components, the material content of FA is analyzed with the help of XRF technology
Figure 2. SEM images of (A and B) Before and after processing of CC; (C and D) Before and after processing of FA.
Figure 3A and B illustrates the morphology of carbon foam composites (CFC) synthesized from the two materials which reveals two distinct morphologies: block and spherical forms within the CFC structure. Furthermore, they demonstrate that both morphological contain macroporous and mesoporous structures with pore sizes ranging from 10 to 500 nm, indicating a significant increase in pore quantity compared to treatments involving FA alone. The emergence and proliferation of these pores suggest that porous carbon is successfully synthesized through the synergistic interaction between CC and FA, resulting in a novel morphology characterized by porous carbon microspheres.
Figure 3. (A and B) SEM images of CFC at different magnifications; (C and D) TEM images of CFC.
To investigate the co-pore formation mechanism between CC and FA and the origin of porous carbon microspheres, we delve into an extensive examination of their preparation process. Supplementary Figure 1 presents the micro-morphology of CC, FA, and CFC precursors following hydrothermal treatment. As observed in Supplementary Figure 1A, numerous carbon microspheres are generated on the surface of CC after water heating. These microspheres exhibit smooth surfaces but display uneven diameters; some appear to be dissolving. Consequently, it can be inferred that these carbon microspheres may gradually detach from larger blocks or spheres over time. Subsequently, controlling hydrothermal duration allows for regulation of the size of these carbon microspheres. Supplementary Figure 1B and C presents scanning electron microscopy images of FA following hydrothermal treatment at varying magnifications. It is evident that the aforementioned phenomenon does not manifest in FA post-hydrothermal reaction; however, under high magnification, irregularly sized pores are observable on the material's surface. This observation supports the hypothesis that metal oxides within FA interact with unburned carbon during hydrothermal processing to create these voids. In contrast, the morphology of the CFC precursor exhibits slight differences compared to the two previously discussed materials [Supplementary Figure 1D and E]. Notably, this material displays both block structures and carbon spheres derived from those blocks simultaneously. As illustrated in
Figure 3C and D shows TEM images of CFC. It can be clearly seen that the material is amorphous carbon and has mesoporous structure with a diameter of about 10-50 nm. From the marked area and the inset part, it can be observed that there are some bright spots of light transmission on the material, which we speculate may be microporous structures. The existence of these microporous structures may be attributed to two factors: on the one hand, the rich element composition inside the CC will react into gas and escape at high temperatures, and on the other hand, CC, as a plant, originally has many micropores. In summary, we successfully prepared CFC porous biomass carbon with abundant macroporous, mesoporous and microporous structures through the synergistic effect of CC and FA. The existence of these pores plays a positive role in electrolyte transport and the active site of electrochemical reaction, which can effectively improve the electrochemical performance of electrode materials.
The elemental composition and chemical bonds of the CFC are further analyzed through the XPS spectra presented in Figure 4. First, the C 1s peak of CFC can be divided into five main components, C=C
Figure 4. XPS deconvoluted spectrum of (A) C 1s, (B) N 1s and (C) O 1s of CFC.
In order to investigate the specific surface area and pore size distribution of the material, nitrogen adsorption/desorption test was carried out. First of all, it can be seen from the above SEM photos that the surfaces of CC and FA before treatment are smooth, and the existence of holes is almost invisible. Since their nitrogen absorption and desorption curves are irregular and do not close, and their specific surface areas are less than 1 m2 g-1, the test results will not be shown or detailed. Supplementary Figure 3 shows the nitrogen absorption and desorption of the three materials after hydrothermal treatment. It can be seen that the absorption and desorption curves of the three materials are all type IV isotherms[50,51]. The failure of the absorption and desorption curves of the CC in Supplementary Figure 3A may be caused by the small specific surface area of the material itself and the insufficient amount of test samples. There is no obvious rapid rise of adsorption lines in the low-pressure region, indicating almost no microporous structure in the three curves. Platforms and hysteresis loops appear in the middle pressure region and the high-pressure region, indicating that they have mesoporous and macroporous structures. In addition, their specific surface area is slightly increased compared with that before treatment, while the specific surface area of FA and mixture is larger, indicating that the addition of FA plays a positive role in the formation of pores, and the preliminary pore-making begins to take effect.
The sample adsorption and desorption curves after activation and carbonization are shown in Figure 5. It can be seen from Figure 5A that the adsorption-desorption isotherm of CC after complete porosity is a type I isotherm[52,53], and there is a steep long platform in this curve, reflecting the reversible adsorption process of a single layer, indicating that the material has a microporous structure. Therefore, it can be concluded that the simple CC porosity can only have a microporous structure, but cannot achieve multi-layer porous carbon structure.
Figure 5. (A-C) Nitrogen adsorption/desorption isotherms and pore size distribution diagram of CC, FAC, and CFC.
Figure 5C shows that the adsorption-desorption isotherm of CFC exhibits a type IV mesoporous characteristic curve; when P/P0 < 0.01, the adsorption line obviously rises rapidly, indicating the existence of micropores in CFC. Further adsorption of N2 reveals a plateau in the adsorption curve where P/P0 is between 0.2-0.5. With the increase of P/P0 from 0.5 to 0.9, the adsorption line gradually rises, forming a H2 hysteresis loop related to capillary condensation, which manifests the characteristics of mesoporous surface. In the range of P/P0 = 0.9-1.0, the adsorption line continues to rise, and does not show an obvious adsorption plateau as it approaches 1.0, exhibiting an H3 hysteresis loop, which indicates the existence of macropore distribution. In addition, the pore size distribution diagram in the illustration shows that the pore size of CFC is mostly concentrated in the ranges of 1.5-1.3, 3.5-4 and 10-15 nm, indicating a combination of microporous, mesoporous and mesoporous structures[54,55].
The same phenomenon can be found in the nitrogen adsorption/desorption curve of FAC [Figure 5B], but the sample has a small distribution of large pores, with a specific surface area of only one-third that of CFC, possibly due to insufficient carbon sources in FA. The above results show that the core-making of FA and CC can greatly increase the specific surface area of carbon materials. On the one hand, CC, as a biomass material, provides a large number of microporous and macroporous channels and a stable carbon source. On the other hand, the macromolecules and unburned carbon in FA itself can be used as templates and self-templates to generate mesoporous structures.
In Figure 6A, the CV plot of the CFC measured by 6 M KOH electrolyte in the three-electrode system is plotted. At negative potential (-0.6-0 V), the curve appears a plateau, indicating that the electrochemical reaction of the CFC at low potential is dominated by charge absorption and desorption, which shows a double-layer capacitance behavior. It can complete the transmission and diffusion of electrons and ions within a short time, manifesting that it has good capacitance characteristics. As the potential increases, the curve reveals the emergence of REDOX peaks within the range of 0.6-1.3 V, indicative of pseudocapacitive behavior. These peaks are attributed to the reversible REDOX reactions of the functional groups doped with heteroatoms during the charge and discharge processes. The XPS spectrum reveals the presence of various nitrogen-containing functional groups within the CFC, including quinoid amine, pyrrole-N, benzene-NH-, and nitrogen cation radicals. The integration of these functional groups contributes to the enhancement of the electrode’s pseudocapacitive characteristics, thereby augmenting its energy storage capacity. At different scanning speeds (1-8 A g-1), the shape of each curve is similar, the response current increases with the rise of scanning speed, and the REDOX peak position rarely has displacement, which indicates that the electrode material has good cycle reversible stability and fast REDOX current response. This phenomenon can also be easily seen from the CV curves of CC and FAC materials in
Figure 6. (A) CV curves at different scanning speeds of CFC, (B) CV curve of CFC, CC and FAC with a scanning speed of 0.1 V s-1, (C) the constant current charge and discharge curve at different current densities of CFC, and (D) the specific capacitance of CFC, CC and FAC.
Electrochemical performances of different precursor electrodes
| Precursor | Electrolyte | Current density | SSA | Specific capacitance | Ref. |
| Reed straw | 6 M KOH | 1 A g-1 | 547.1 m2 g-1 | 202.8 F g-1 | [56] |
| Peanut shell | 6 M KOH | 1 A g-1 | 2,764 m2 g-1 | 228 F g-1 | [57] |
| Biomass fulvic acid | TEABF4/PC | 1 A g-1 | 1,938 m2 g-1 | 107 F g-1 | [58] |
| Fatsia japonica | 6 M KOH | 1 A g-1 | 870.3 m2 g-1 | 140 F g-1 | [59] |
| Ambrosia melon peels | 1 M H2SO4 | 1 A g-1 | 529.9 m2 g-1 | 200 F g-1 | [60] |
| Passion fruit husks | 1 M trifluoroacetic acid | 1 A g-1 | 1,858 m2 g-1 | 297.1 F·g-1 | [61] |
| Camellia | 1 M KOH | 2 A·g-1 | / | 125.42 F·g-1 | [62] |
| Corncob and fly ash | 6 M KOH | 1 A g-1 | 1,768 m2 g-1 | 240 F g-1 | This work |
Except for the research on the electrical properties for SC of CFC, we also assemble a half-cell using the lithium sheet as the counter electrode to test its lithium storage performance in a lithium electrolyte. Figure 7A is the CV map of CFC measured at different sweep speeds under the voltage window of
Figure 7. (A) CV curves at different scanning speeds of CFC half-cell, (B) magnification performance of CFC half-cell, (C) cycle performance of CFC half-cell.
CONCLUSIONS
In this study, biomass carbon (CC) and industrial waste (FA) are successfully employed together for the preparation of CFC through the hydrothermal method and KOH activation, thereby achieving waste recycling. The results showed that the participation of FA effectively increased the mesoporous ratio of the material and thus enriched the specific surface area of the material. Simultaneously, a considerable number of carbon microspheres generated in the hydrothermal process of biomass CC enriched the microstructure of the electrode material and increased the heteroatom doping site. In the three-electrode test, CFC shows a maximum specific capacitance of 240 F g-1 (at 1 A g-1), and even at 8 A g-1, the specific capacitance can reach over 100 F g-1, with good reversibility and magnification performance. In addition, CFC also displays excellent lithium storage capacity. When the current density is 0.1 A g-1, the first discharge specific capacity of the assembled Li|CFC capacitor is about 160 mAh g-1, and the specific capacity can be maintained at
DECLARATIONS
Authors’ contributions
Conceived the ideas of the work and carried out the basic characterization, including TEM and SEM measurement, prepared the devices and performed most measurements, including CV, GCD, and cyclic stability: Ruan, S.
Helped to conduct the measurements and analysis: Huang, H.; Gan, Y.
Involved in the data analysis and wrote the final version of the manuscript: Ruan, S.; He, X.; Xia, Y.
Supervised this project: Zhang, J.; Zhang, W.; Xia, X.
Analyzed the data and contributed to the discussions: Ruan, S.; He, X.; Huang, H.; Gan, Y.; Xia, Y.; Zhang, J.; Wan, W.; Wang, C.; Xia, X.; Zhang, W.
Availability of data and materials
The rata data supporting the findings of this study are available within this Article and its Supplementary Material. Further data are available from the corresponding authors upon request.
Financial support and sponsorship
This work is supported by Department of Science and Technology of Zhejiang Province (Grant No. 2023C01231), Key Scientific Research Project of Hangzhou (Grant No. 2024SZD1B12), National Natural Science Foundation of China (Grant Nos. 52372235, 52073252, KYY-ZX-2020050), Postdoctoral Research Project of Zhejiang Province (ZJ2024101), and Key Laboratory of Engineering Dielectrics and Its Application (Harbin University of Science and Technology), Ministry of Education (KFM 202302).
Conflicts of interest
All authors declared that there are no conflicts of interest.
Ethical approval and consent to participate
Not applicable.
Consent for publication
Not applicable.
Copyright
© The Author(s) 2025.
Supplementary Materials
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Ruan, S.; He, X.; Huang, H.; Gan, Y.; Xia, Y.; Zhang, J.; Wan, W.; Wang, C.; Xia, X.; Zhang, W. Innovative approaches of porous carbon materials derived from energy waste and their electrochemical properties. Energy Mater. 2025, 5, 500066. http://dx.doi.org/10.20517/energymater.2024.217
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