Introduction
Hard carbon (HC), endowed with abundant raw resources, is a non-graphitized carbon material distinguished by graphite microcrystals, turbulent layers, and nanopores. Within sodium-ion battery systems [1, 2], the HC anode shows prolonged and reversible charge/discharge plateaus at low potentials (lower than 0.1 V), reminiscent of the electrochemical characteristics observed in graphite anodes within lithium-ion battery systems [1–5]. This suggests that HC is a promising anode material for commercial sodium-ion batteries [6–9], and compared with alloy-based materials, titanium-based materials, and so forth, HC materials have outstanding economic advantages due to high technological maturity and abundant resources [10–12].
Researchers have extensively explored diverse HCs derived from various precursors and synthesis conditions. Nevertheless, HC with plentiful defects and sodium-ion-irreversible pores presents challenges, including low initial Coulombic efficiency, sluggish sodium storage kinetics, and unstable cycling performance [13, 14]. Varying carbonization temperatures during HC synthesis can minimize defects and promote the formation of larger graphite-like domains, which aids in the insertion of sodium ions into interlayers and boosts plateau capacity [15, 16]. However, excessively high temperatures shrink the interlayer spacing, hindering sodium-ion intercalation. When heated to 2000°C, the plateau capacity becomes undetectable [17]. In addition to optimal layer spacing, the presence of closed nanopores is crucial for storing sodium [18, 19]. Recent persuasive studies have highlighted that closed pore structures provide excellent plateau capacity [20, 21]. However, creation of these closed pores presents significant challenges. Conventional methods often struggle with controlling pore size and distribution, and maintaining structural integrity during carbonization. For instance, Wang et al. adopted a high-temperature carbonization pathway following KOH chemical activation of anthracite, which initially produced open-pore disordered carbon [22]. These were later converted into closed pores within short-range carbon structures, achieving a capacity of 308.4 mAh g−1, primarily contributed by the low-voltage platform. Zheng et al. developed a CO2-etching and carbonization strategy that induced numerous closed nanopores [23]. This technique enhanced both the size and the storage capacity of the closed pores, while preserving the microsphere shape, resulting in a plateau capacity of 351.1 mAh g−1.
Herein, we utilize zinc gluconate (ZG)-assisted carbonization of low-cost lotus seed shell waste to fabricate HC anodes for SIBs. Without multiple steps or harsh conditions, the HCs are prepared using a facile one-step pyrolysis process, which significantly reduces defects and introduces nanopores. This straightforward strategy enables the transformation of ZG into zinc oxide and its eventual volatilization at elevated temperatures to create extensive nanopores and etched carbon microcrystals. The resulting microstructure features curved, long-layered graphene with well-distributed nanopores and optimal layer spacing. Moreover, the persistence of trace zinc atoms as single atoms within the HC matrix enhances sodium-ion transport and recombination rates. These isolated metal atoms function similarly to non-metallic heteroatoms, providing a uniform coordination structure that minimizes the formation of electrochemically irreversible sites. The constructed carbon anode shows a remarkable reversible capacity of 348.5 mAh g−1 with an excellent initial Coulombic efficiency (ICE) of 92.84%, along with excellent cycling stability (90.05% capacity retention after 500 cycles) and outstanding rate capability (218.0 mAh g−1 at 500 mA g−1), making it a commercially viable solution.
Result and Discussion
In this research endeavor, advanced HC anodes are developed utilizing cost-effective lotus seed shells as the primary material. The precursor is milled with ZG to establish essential cross-links with zinc ions, which catalytically integrate short-range graphite fragments into extensive, low-defect graphitic layers during pyrolysis (Supporting Information S1: Figure S1). Carbonization is conducted at three different temperatures (1200°C, 1400°C, and 1600°C), resulting in three samples denoted as HC-1200, HC-1400, and HC-1600 (Figure 1A). Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) analyses show that all samples have a blocky structure with abundant channels, both on the surface and internally (Supporting Information S1: Figure S2). However, the carbonization temperatures strongly influenced the microstructures. Specifically, as depicted in Figure 1B, the high-resolution TEM (HRTEM) image of HC-1200 displays a short-range disordered lattice. In contrast, HC-1400 shows long-range curved graphene layers that contain a significant number of nanopores; these structural features enhance the effective transportation and retention of Na+ (Figure 1C). On increasing the temperature to 1600°C, further graphitization occurs, resulting in the formation of thicker carbon layers. This narrowing of the interlayer spacing subsequently hinders the intercalation of Na+ ions (Figure 1D). The selected area electron diffraction (SAED) patterns provide confirmation of the structural changes that have occurred, with HC-1200 showing enhanced disorder and HC-1600 indicating increased graphitization (Supporting Information S1: Figure S3) [24–26]. This result indicates that as the carbonization temperature increases, pore size also increases due to the merging of micropores into mesopores, and the degree of microstructure ordering and graphitization also improves, albeit at the cost of reduced interlayer spacing. This study highlights the balance required between graphitization and interlayer spacing to optimize Na+ ion storage and transport in HC anodes.
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X-ray diffraction (XRD) and Raman tests are utilized to analyze and compare the microstructural differences among the various samples. XRD patterns (Figure 1E) clearly distinguish the crystallographic properties of HC-1200, HC-1400, and HC-1600. All three samples inherit peaks at approximately 23° and 43°, which can be attributed to the characteristic (002) and (100) crystal planes, respectively, of disordered graphite domains [27]. As the carbonization temperature increases, the (002) peak undergoes a shift toward a higher angle, accompanied by a notable sharpening effect, indicating more ordered graphitic microcrystals, enhanced crystallization, and reduced interlayer spacing. According to HRTEM analysis, the layer spacings of HC-1200, HC-1400, and HC-1600 are 0.44 nm, 0.38 nm, and 0.35 nm, respectively, showing excellent agreement with the XRD results. Typically, a reduction in defects and an elevation in the level of graphitization occur. This, in turn, results in a lower intensity ratio of the D-band to the G-band (ID/IG) in Raman analysis [28]. Surprisingly, contrary to expectations, the ID/IG ratio increases from 0.93 to 1.27 as the pyrolysis temperature increases (Figure 1F). This anomaly may be ascribed to the presence of abundant closed pores in HC-1600, which contribute to the disorder [29]. Furthermore, elemental mapping (Supporting Information S1: Figure S4) unveils the uniform dispersion of C, N, and O in the HC-1400 sample. Fourier transform infrared spectroscopy (FTIR) further confirmed the C═O and C–N sites (Figure 1G) [30]. This shows that ZG-assisted carbonization not only retains nonmetallic elements from the native material but also facilitates sodium-ion storage capability through the adsorption of sodium by the detected functional groups. Overall, these findings indicate that higher carbonization temperatures lead to increased graphitization and closed pore formation, which can influence the material's disorder and sodium storage properties.
To examine the effect of the carbonization process on the phase composition of HC and ZG mixtures, we analyzed the structural evolution and nanopore formation at various temperatures of 100, 200, 400, 600, 800, and 1000°C (denoted as ZG/HC-200, ZG/HC-400, ZG/HC-600, ZG/HC-800, and ZG/HC-1000, respectively). The XRD patterns of the pristine HC and ZG at room temperature (Supporting Information S1: Figure S5) reveal distinct peaks for each ingredient. Upon mixing, XRD reveals the emergence of broad shoulder peaks attributed to the pristine HC, alongside intricate diffraction peaks stemming from the ZG component. As the carbonization process (Figure 2A) proceeds, noticeable changes begin at 100°C, primarily due to the decomposition of ZG. At 200°C, significant decomposition of ZG takes place, resulting in the disappearance of characteristic peaks associated with the products, leaving behind amorphous characteristics. In this process, the molecules of ZG undergo degradation, leading to the volatilization of gas products and the generation of residual organic molecules. Upon reaching 400°C, the formation of zinc oxide crystal initiates, with their crystallinities and sizes continuing to increase above 600°C. As the temperature further increases, there is a slight catalysis of partial graphitization of the HC. Concurrently, a bulk-etching phenomenon is observed within the graphitic layers by the reaction ZnO + C = Zn + CO↑, mostly producing metallic Zn, which can evaporate above 900°C [31]. Notably, this process results in the formation of plenty of small voids within HC, further impeding directed graphitization and generation of a large number of nanopores. However, as the carbon layer densifies, a minute portion of internal ZnO is reduced to form zinc monoatoms, which become embedded within the HC. This phenomenon is reflected in the subsequent characterization. HRTEM images (Supporting Information S1: Figure S6a,b) demonstrate that ZG/HC-200 displays a high degree of disorder, and as the temperature increases, ZnO begins to emerge at 400°C, with a small amount of ZnO lattice becoming visible (Figure 2B,C). The appearance of ZnO persists at 600°C (Figure 2D,E), where metal lattice is scarcely observed and smaller nanopores begin to appear. At 800°C (Figure 2F,G), nanopores continue to grow, and the carbon layer becomes slightly more ordered. Further heating to 1000°C results in additional growth of nanopores, accompanied by a slight improvement in carbon layer orderliness (Supporting Information S1: Figure S6c,d). TEM results align well with XRD findings, illustrating that the formation of closed pores during ZG/HC pyrolysis involves the initial embedding of ZG into the carbon matrix, followed by the growth of ZnO to metallic Zn, which was then eliminated by high-temperature volatilization. The small amount of residual Zn within the HC contributes to the migration of sodium ions. The continuous development of graphite domains and shrinkage of partially open pores drive the transformation of open pores into closed pores.
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In Figure 3A, the nitrogen adsorption–desorption isothermals for samples show a characteristic type IV adsorption curve, indicating a sharp pore size distribution that is concentrated primarily around 3.8 nm (Figure 3B), ideal for Na+ ion diffusion. The pore numbers decrease with increasing temperature [32, 33]. The nitrogen adsorption–desorption measurements show sensitivity exclusively to the examination of external pore structures (those open, interconnected with the external environment), rendering them unsuitable for the analysis of internal pore structures (closed pores, enclosed areas within the material). During the process of carbonization at high temperatures, the formation of microcrystalline structures during a process can cause some external pore structures to transform into internal ones [34]. Figure 3C displays the microstructure of the samples obtained from small-angle X-ray scattering (SAXS) method. In the SAXS spectra, the medium region shows scattering from nanometer-sized structures, attributed to nanopores in HC. The lower Q region of the spectrum indicates scattering originating from larger-scale microstructural features, such as meso/macropores and particles. SAXS curves at ≈ 0.01-0.2 Å−1 (Figure 3C inset) suggest an intensification of nanopore scattering as the charring temperature increases, suggesting the growth of closed nanopores. This phenomenon arises from the fusion of cellulose and other substances into a graphite-like layer, which contract in the presence of Zn to form closed pores [29]. The brightness of 2D SAXS images indicates a rich isotropic pore distribution, confirming diverse porosity (Figure 3D). The results of nanopore growth are consistent with the distribution of nanopore in HRTEM. The elemental makeup and states were investigated using X-ray photoelectron spectroscopy (XPS). The oxygen content of HC-1600 (3.53%) is significantly lower than that of HC-1200 (4.37%), indicating a loss of sp3-hybridized carbon and C–O functional groups in the high-temperature carbonization process (Figure 3E, Supporting Information S1: Figure S7). The reduced oxygen content can minimize the initial capacity loss from irreversible Na+ adsorption, enhancing the ICE and favoring practical electrode application [35, 36]. Additional, XPS results confirm the presence of Zn in the HC-1400 material. The elemental analysis by inductively coupled plasma mass spectrometry (ICP-MS) shows a Zn content of 0.005 wt% (Supporting Information S1: Table S1). The high-angle annular dark-field scanning transmission electron microscopy (HAADF-STEM) image displays a sparse, evenly distributed scattering of bright spots across the HC substrate (Figure 3F), revealing the atomic dispersion of Zn species. These trace zinc single atoms boost the ion transport rate [37].
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To further elucidate the role of zinc single atoms, density functional theory (DFT) calculations are used to explore their impact on Na+ storage kinetics. Two idealized models, graphite without metal atoms (GR) and graphite with zinc single atoms (Zn-GR), are constructed based on the microstructural features of HC. These models are used to simulate the Na+ diffusion process within the graphite domains of Zn-HC and HC (Figure 3G,H). The adsorption sites and corresponding Na+ adsorption energies are shown in Supporting Information S1: Figure S8, where GR shows a lower adsorption energy (−4.52 eV) compared to Zn-GR (−2.41 eV), suggesting that Zn single atoms do not serve as active sites for Na+ adsorption. However, the calculated Na+ diffusion energy barrier for Zn-GR (0.36 eV) is significantly lower, indicating that Zn single atoms promote Na+ diffusion, which is a key factor contributing to the material's excellent rate capability (Figure 3I).
Building on these results, we carried out an in-depth exploration of the electrochemical characteristics of the materials utilized within a battery system. Charge/discharge curves of HC-1200, HC-1400, and HC-1600 half-cells show distinct regions at the slope and plateau region, indicating quintessential sodium-ion storage behavior observed in HC materials (Figure 4A and Supporting Information S1: Figure S9). The obvious potential plateau visible in the charge curve of HC-1400 at approximately 0.5 V is attributed to a redox reaction involving Na+ and C═O [38, 39]. It is noteworthy that the sloping region associated with the C═O reduction reaction may be influenced by factors such as the C═O group and defects, potentially resulting in slopy charge/discharge behavior [40]. HC-1600, characterized by fewer defect counts and a decreased specific surface area, displays a notable high-voltage plateau. Conversely, HC-1200, with a higher defect content and lower degree of graphitization, displays an overall gradual charge/discharge curve [32, 34, 38, 41, 42]. Remarkably, HC-1400 delivers a much greater initial reversible capacity of 348.5 mAh g−1 at 30 mA g−1, compared to HC-1200 (224.9 mAh g−1) and HC-1600 (274.5 mAh g−1). Additionally, it achieves an ICE of 92.84%. The HC without ZG displays a capacity of 291.0 mAh g−1, with an ICE of 86.60% (Figure 4A). This enhancement is attributed to its ultra-small nanopores that selectively allow Na ion insertion while preventing electrolyte molecules from accessing the inner surface, thereby effectively avoiding excessive SEI film formation. Similar results are found in the cyclic voltammetry (CV) curve, which shows an irreversible redox peak in the first cycle, indicating electrolyte decomposition and the formation of an SEI film, accompanied by minimal side reactions (Figure 4C). The CV curve shows repetition in subsequent cycles and has a prominent redox peak pair within a low potential range. This observation suggests that the storage of sodium ions within the carbon matrix has excellent reversibility (Supporting Information S1: Figure S10). More detailed analysis reveals that the plateau portion of HC-1400 (0.1–0.01 V) constitutes 69.50% of the total capacity, surpassing HC-1200 and closely aligning with HC-1600 (Figure 4B). Such a salient plateau capacity in HC-1400 can be attributed to its abundance of closed pores, recognized as superior Na+ storage sites [23]. These findings emphasize the link between Na+ storage capacity and a closed pore structure [22]. Furthermore, HC-1400 demonstrates outstanding rate capability, achieving an excellent capacity of 218.1 mAh g−1 at 500 mA g−1, outperforming HC-1200 and HC-1600, which have capacities of 162.8 and 146.9 mAh g−1, respectively (Figure 4D). Although the capacity reduction at high current densities is partly attributable to the sluggish kinetics of closed pores serving as Na+ storage sites, the presence of zinc single atoms significantly enhances ion transport rates, thereby improving high current densities performance compared to other biomass-derived carbon materials. All samples demonstrate remarkable stability over multiple cycles. Particularly noteworthy is HC-1400, which maintains a capacity of 340.5 mAh g−1 after 50 cycles, even at a current density of 30 mA g−1 (Figure 4E). Furthermore, at higher current densities, HC-1400 demonstrates impressive performance, retaining 90.05% capacity after 500 cycles at 200 mA g−1 and 86.02% after 1000 cycles (Figure 4F). In addition, the properties of electrode materials obtained by mixing HC with different mass ratios of ZG are compared (HC:ZG = 1:0.5 or 1:2). Too little ZG results in a synthesized hard carbon material without a rich closed pore structure, while too much ZG results in a large amount of Zn volatilizing at high temperatures to produce an unclosed pore, leading to a low ICE. And the HC-1400 anode shows the best rate performance and long cycle Performance (Supporting Information S1: Figure S11). Comparative analysis with previous reports on biomass-derived carbon materials highlights the significantly higher reversible capacity and ICE of the as-prepared HC-1400 (Figure 4H) [38, 43–52]. In a practical application, HC-1400 serves as an anode paired with a Na3V(PO4)3 cathode to construct a full cell. Also, this full cell demonstrates a high discharge capacity of 265.0 mAh g−1. Additionally, it offers an output voltage of 3.2 V and maintains excellent capacity retention of 60.83% even after 100 cycles (Figure 4G and Supporting Information S1: Figure S12). These results highlight its significant potential for practical commercial applications.
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In order to investigate the impact of microstructural modifications on the storage behavior of sodium ions, a kinetic study of HC-1400 was carried out using CV and the galvanostatic intermittent titration technique (GITT). The CV curves of HC-1400 were recorded at various scan rates of 0.2 ~ 1 mV s−1 (Figure 5A). On the basis of the relationship between current and scan rate, the storage behavior of Na+ can be calculated from the b-value using the following formulas:
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To gain a deeper insight into how HC-1400 stores sodium in the low-voltage plateau region, the HC electrodes discharged to 0.5 V, 0.05 V, 0.03 V and 0.01 V were disassembled and soaked in a solution of phenolphthalein/ethanol. And sodium quasi-metal reacts with ethanol to form H2 and CH3CH2ONa. When the reaction occurs, it causes the phenolphthalein solution to turn red [23]. As the discharge process continues, the color of the ethanol solution gradually intensifies (Figure 5E). When discharged to 0.01 V, a large amount of H2 gas is produced when the pole piece comes into contact with the solution, and the solution becomes darker in color, indicating the presence of quasi-metallic sodium in the nanopores of the HC-1400 material, which corresponds to the Na filling process. In addition, the electrode was analyzed using GITT with a pulse current of 30 mA g−1 (Supporting Information S1: Figure S17), and the corresponding diffusion coefficients () are presented in Figure 5F [38, 56]. Impressively, in the slope region, where the value stabilizes, a high level of Na+ diffusivity is observed during the adsorption process that occurs on the surface of the carbon material. In the plateau region, values decrease and then increase; the sharp decline in values within the range of approximately 0.1 to 0.05 V is attributed to the intercalation of Na+ through the carbon layer with the interior of HC-1400, whereas at 0.05 V, the diffusion coefficient shows an extremely rapid increase, which is attributed to the sodium ions starting to fill the nanopores. The findings suggest that sodium ions primarily undergo three processes: adsorption in the slope region, intercalation into the carbon layers, and subsequent reduction to form sodium clusters that fill the enclosed pores. In summary, the material follows an “adsorption–intercalation–pore filling” sodium storage mechanism.
Conclusions
In summary, we have developed a HC material with low defects, abundant nanopores, and long-order curved graphite domains using a facile ZG-assisted catalytic process. The conversion of ZG into ZnO during preparation results in HC with expanded interlayer spacings, abundant turbostratic nanoregions, and closed pores. With an increase in temperature, a large amount of ZnO is reduced and volatilized at high temperatures. Additionally, trace amounts of single zinc atoms remain in the HC, significantly enhancing ion-transfer mobility. Our comprehensive investigation confirms the coexistence of interlayer Na+ intercalation and nanopore Na filling in the low-voltage plateau region during cycling. This dual mechanism, driven by both optimal layer spacing and nanopores, underpins the excellent performance of the HC material. Consequently, the HC-1400 electrode achieves a capacity of 348.5 mAh g−1, with an ICE of 92.84%, demonstrating its potential for use as a high-performance anode material for sodium-ion batteries.
Acknowledgments
Y. Z. acknowledges the support from the National Natural Science Foundation of China (22209103). H.G. and Y.W. acknowledge the support from the Open Project of State Key Laboratory of Advanced Special Steel, the Shanghai Key Laboratory of Advanced Ferrometallurgy, Shanghai University (SKLASS 2021-04), the Science and Technology Commission of Shanghai Municipality (22010500400) and “Shanghai Pujiang Program” (23PJ1402800), “Joint International Laboratory on Environmental and Energy Frontier Materials,” and “Innovation Research Team of High-Level Local Universities in Shanghai” at Shanghai University.
Conflicts of Interest
The authors declare no conflicts of interest.
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Abstract
ABSTRACT
Hard carbons are promising anode materials for sodium‐ion batteries (SIBs), but they face challenges in balancing rate capability, specific capacity, and initial Coulombic efficiency (ICE). Direct pyrolysis of the precursor often fails to create a suitable structure for sodium‐ion storage. Molecular‐level control of graphitization with open channels for Na+ ions is crucial for high‐performance hard carbon, whereas closed pores play a key role in improving the low‐voltage (< 0.1 V) plateau capacity of hard carbon anodes for SIBs. However, creation of these closed pores presents significant challenges. This work proposes a zinc gluconate‐assisted catalytic carbonization strategy to regulate graphitization and create numerous nanopores simultaneously. As the temperature increases, trace amounts of zinc remain as single atoms in the hard carbon, featuring a uniform coordination structure. This mitigates the risk of electrochemically irreversible sites and enhances sodium‐ion transport rates. The resulting hard carbon shows an excellent reversible capacity of 348.5 mAh g−1 at 30 mA g−1 and a high ICE of 92.84%. Furthermore, a sodium storage mechanism involving “adsorption–intercalation–pore filling” is elucidated, providing insights into the pore structure and dynamic pore‐filling process.
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Details
; Liu, Hao 5
1 Joint International Laboratory on Environmental and Energy Frontier Materials, School of Environmental and Chemical Engineering, Shanghai University, Shanghai, China
2 Joint International Laboratory on Environmental and Energy Frontier Materials, School of Environmental and Chemical Engineering, Shanghai University, Shanghai, China, State Key Laboratory of Advanced Special Steel, Shanghai Key Laboratory of Advanced Ferrometallurgy, Shanghai University, Shanghai, China
3 School of Chemistry and Materials Science, Jiangsu Normal University, Xuzhou, Jiangsu, China
4 Faculty of Materials Science and Energy Engineering, Shenzhen University of Advanced Technology, Shenzhen, Guangdong, China
5 Centre for Clean Energy Technology, University of Technology Sydney, Sydney, New South Wales, Australia
6 College of Chemistry and Materials Engineering, Wenzhou University, Wenzhou, China