Exploring advanced battery materials with fast charging/discharging capability is of great significance to the development of modern electric transportation. Herein we report a powerful synergistic engineering of carbon and deficiency to construct high-quality three/two-dimensional cross-linked Ti2Nb10O29−x@C composites at primary grain level with conformal and thickness-adjustable boundary carbon. Such exquisite boundary architecture is demonstrated to be capable of regulating the mechanical stress and concentration of oxygen deficiency for desired performance. Consequently, significantly improved electronic conductivity and enlarged lithium ion diffusion path, shortened activation process and better structural stability are realized in the designed Ti2Nb10O29−x@C composites. The optimized Ti2Nb10O29−x@C composite electrode shows fast charging/discharging capability with a high capacity of 197 mA h g−1 at 20 C (∼3 min) and excellent long-term durability with 98.7% electron and Li capacity retention over 500 cycles. Most importantly, the greatest applicability of our approach has been demonstrated by various other metal oxides, with tunable morphology, structure and composition.
In today’s society, lithium ion batteries (LIBs) are continuing to boom to meet the growing demand of smart electronics (i.e., smartphones, laptops, etc.) and electric vehicles (EVs)1,2. With sales rising of EVs and demand for smartphones slowing, it is reasonable to believe that EVs will dominate the demand for LIBs in the near future. For a decade, with the adoption of high-energy electrode materials, LIB technology is developing rapidly and new EV models are being rolled out with much improved mileage range. However, compared with mileage range, charging time in a few minutes, rather than hours, has already become the major concern in the EV industry. Apparently, exploring high-power electrode materials with fast charge/discharge capability is highly desirable to alleviate this technological challenge and enable the development of new power-intensive devices3,4,5,6.
The high-speed storage of electrical energy critically depends on the facile transport of Li ions and electrons in the electrode materials, for which the improvement of the lithium mobility and electronic conductivity is the key of success. Currently, various techniques and approaches have been developed in order to achieve the high-rate electrodes. Among them, the strategy of building nanostructured materials is the most direct and effective one, because the increased surface area can provide more active sites in contact with electrolyte, and the reduced length of diffusion path also fastens the transport of electron and Li+7,8,9. However, this strategy alone still makes it difficult for the electrode materials to perform well because most battery electrodes have intrinsically low electrical conductivity. In such a context, another important approach, carbon coating, has also been frequently used in both bulk and nanostructured electrodes to optimize the power capability. To date, numerous carbon-coated electrodes, such as LiFePO4/C10 and Si/C11, have been developed via various technologies including atomic layer deposition (ALD)12, molecular layer deposition (MLD)13, hydrothermal14, electrodeposition15, and chemical vapor deposition16,17. Despite the substantial efforts, however, these carbon-coating techniques are still far away from the requirements of industry for their drawbacks, such as high cost and complex synthetic control. For example, ALD and MLD methods fabricate carbon shell from converting organic polyamide film, which usually involves high-temperature treatment (>600 oC) and long-time operation. In addition, such uneconomical process has also been frequently used in other carbon-coating techniques like hydrothermal and electrochemical depositions. Furthermore, previous studies have been mainly focused on the uniform carbon coating at the secondary-particle level, which can only take effect on the enhancement of intrinsic conductivity and alleviation of mechanical stress with varying degree of success. Considering the power capability of LIBs depends extremely on the enhanced intrinsic conductivity of every individual grain, carbon coating at the primary-grain level will inherently result in the reinforced rate capability. Given all that, it is highly desirable to fully take advantages of both nanostructuring and carbon-coating techniques. And meanwhile to develop a facile and practical strategy, which can realize boundary carbon coating, which means that the carbon can coat on the active materials at primary-grain level with good conformity and adjustable thickness.
In this work, a facile and controllable low-temperature carbon-coating technique has been developed by controlling acetylene decomposition process. In a departure from other approaches, our strategy is capable of creating a uniform carbon coating with desired thickness at primary-grain level, which inherently results in high charge and discharge rate in the nanostructured electrode. As an instance, we demonstrate that with this appropriate low-temperature treatment, the conductive carbon with tunable thickness can be uniformly coated on boundary of nanostructured Ti2Nb10O29 (TNO), allowing the rationally designed Ti2Nb10O29−x@C (TNO−x@C) composites to be used at extremely high rates (197 mA h g−1 at 20 C, corresponding to a charge time of 3 min). Compared with the pure TNO, the significantly improved performance can be ascribed to the enhanced electronic conductivity, improved Li ion diffusion properties and unexpected defective chemistry. Also, our in situ high-energy synchrotron X-ray diffraction (HEXRD) results show that the lattice anisotropy of TNO−x@C has also been significantly weakened during the operation. Importantly, we further demonstrate the generality of this uniform engineering of carbon, which can be applied to achieve other high-rate metal oxides such as Nb2O5−x@C microrods, TiO2−x@C nanoparticles and ZnO−x@C nanorods.
Synthesis and structural characterization of the products
As shown in Supplementary Fig. 1–2, puffed rice carbon (PRC) was employed as sacrificial template to obtain three dimensional (3D) hierarchical porous TNO network. A 3D hierarchical microcellular porous morphology was observed for the PRC, which consisted of interconnected secondary carbon sheets18. After solvothermal process and annealing in air, the sacrificial PRC template was decomposed and left a 3D hierarchical porous TNO network composed of cross-linked secondary nanosheets and tertiary nanoparticles with an average grain size of 50 nm and pore size of 10–50 nm (Supplementary Fig. 3). Followed by the controllable acetylene decomposition, the TNO primary grains were uniformly coated with carbon shells, forming 3D hierarchical porous Ti2Nb10O29−x@C (TNO−x@C) composites. The thickness of the boundary carbon could be controlled by the reaction temperature. In our case, three kinds of carbon thicknesses (1 nm-350 °C; 3 nm-400 °C; 5 nm-450 °C) were realized in the TNO−x@C composites and referred as TNO−x@C1, TNO−x@C3, and TNO−x@C5, respectively (Fig. 1a–c and Supplementary Fig. 4). Note that the porous architectures are still well preserved in all the TNO−x@C composites, indicating that the boundary-coated carbon from the acetylene decomposition makes no contribution to the overall morphology.
The microstructure evolutions of the products at different stages were investigated by transmission electron microscope (TEM). Consistent with the scanning electron microscope (SEM) results, the pure porous TNO nanosheets are composed of interconnected TNO nanograins of 50–60 nm with pore size of 10–50 nm (Supplementary Fig. 5a–b). The as-prepared TNO nanosheets are highly crystalline, as revealed by the high-resolution TEM (HRTEM) images (Supplementary Fig. 5c) as well as the selected area electron diffraction (SAED, Supplementary Fig. 5c inset) pattern. After controllable acetylene decomposition, interestingly, each primary TNO grain was homogeneously decorated with high-quality carbon layer with a thickness of ~3 nm produced at 400 °C (Fig. 1d–f). Similarly, uniform carbon coating was also achieved in the TNO−x@C1 and TNO−x@C5 composites (Supplementary Fig. 5d–i). In the light of similar morphology, the TNO−x@C3 composites are selected for the further discussion. The fine microstructure of TNO−x@C3 composites was investigated using scanning TEM (STEM) equipped with high-angle annular dark-field (HAADF) and annular bright-field (ABF) detectors. In the HAADF images (Fig. 1g, h), the atomic arrangements are represented with bright spots, in which the Ti/Nb sites are much brighter than the O sites due to the stronger scattering capability of electrons for high-Z atoms. Interplanar d-spacings of 18.8 Å and 15.7 Å corresponding to (001) and (100) planes are observed, demonstrating the presence of monoclinal Ti2Nb10O29 phase (JCPDS 72-0159) (Fig. 1g, h)3,19,20. It is known that the contrast of ABF image is highly sensitive to the light elements like O. Faint dark spots are visible at the O sites with fluctuant contrast, which was revealed by the inconsistent peak valley of the line profile (Fig. 1i). In addition, the weakening of the oxygen contrast firmly proves the abundant oxygen vacancies in the TNO−x@C321. The introduction of the oxygen vacancies at TNO−x could be due to the reduction of TNO by H2, which is generated from the decomposition of acetylene (C2H2): C2H2 = 2C + H2. In other words, the acetylene plays two important roles in the formation of TNO−x@C3 composites. On the one hand, the acetylene acts as the boundary carbon source, which deposits outside the primary grains of TNO during the decomposition process. On the other hand, the concomitant H2 could reduce TNO to produce the oxygen vacancy resulting in defective TNO−x. Such dual effects arising from the acetylene decomposition is unique and cannot be realized by the previous carbon-coating technologies. The uniformity of TNO−x@C3 was also verified by energy dispersive spectrometer (EDS) mapping. The elements of Ti, Nb, O, and C homogeneously distribute in the TNO−x@C3 sample (Fig. 1j), indicating the successful synthesis of TNO−x@C3 composites. It is noteworthy that our developed synergistic engineering of carbon and deficiency can be highly applicable to other metal oxides with tunable morphology, composition, and structure including TNO−x@C microspheres (Supplementary Fig. 6–7), Nb2O5−x@C microrods, TiO2−x@C nanoparticles, and ZnO−x@C nanorods (Supplementary Fig. 8). In a nutshell, the newly developed engineering of carbon and deficiency is a powerful method to simultaneously implement the conformal coating of boundary carbon layer and introduction of abundant oxygen deficiencies in various metal oxides. The phase evolution was monitored by X-ray diffraction (XRD) tests (Fig. 2a and Supplementary Fig. 9a). The diffraction peaks of all the samples could be well indexed to the Ti2Nb10O29 phase (JCPDS 72-0159)22, suggesting that the coating of boundary carbon does not affect the phase purity of TNO. Raman measurements were conducted to confirm the existence of the carbon-coating layer (Fig. 2b and Supplementary Fig. 9b). For the pure unmodified TNO nanosheets, the characteristic peaks at 264, 649, 894, and 1003 cm−1 are clearly recognized, matching well with the Ti2Nb10O29 phase. As for the TNO−x@C3 sample, apart from the above characteristic peaks of TNO, two newly emerged Raman peaks at 1352 cm−1 (disorder induced D-band) and 1585 cm−1 (a graphitic G-band) are detected and the intensity ratio of G-band to D-band (IG/ID) was about 1.30, suggesting the existence of carbon layer and its high crystallinity. Moreover, the IG/ID ratio of TNO−x@C3 sample was higher than those of TNO−x@C1 and TNO−x@C5 samples, indicating the optimal crystallinity of carbon in the TNO−x@C3 sample. Thermogravimetric (TG) analysis (Supplementary Fig. 9c) demonstrates that the contents of carbon in the TNO−x@C1, TNO−x@C3, and TNO−x@C5 composites are 2.3, 3.2, and 6.8 wt.%, respectively, implying the controllable carbon coating by acetylene decomposition.
To study the oxygen deficiencies of the samples, electron paramagnetic resonance (EPR) tests were carried out. The TNO−x@C3 shows the strongest EPR signal at g = 2.0 (typical signal of oxygen vacancies) (Supplementary Fig. 9d), higher than those of TNO−x@C1 and TNO−x@C5 counterparts, while the pure TNO nanosheet sample only displays a flat line without obvious oxygen vacancy23,24. These results clearly confirm the presence of abundant oxygen deficiencies in TNO−x@C3. The TNO−x@C3 was also chosen as a representative to study its physicochemical property based on the optimized carbon layer and oxygen deficiency (Fig. 2c). As observed from X-ray photoelectron spectra (XPS, Fig. 2d), the O 1 s spectra of pure TNO nanosheets only presents an individual peak at 531.0 eV, belonging to metal-O bonding8,23,24. However, apart from the metal-O bonding, the TNO−x@C3 nanosheets also exhibit another peak characteristic of metal-OH bonding (532.6 eV), further indicating the existence of oxygen deficiencies in TNO−x@C38,23,24. Meanwhile, the valence state change of Ti and Nb caused by oxygen deficiency is also proven by the Ti 2p and Nb 3d XPS spectra (Supplementary Fig. 9e–f)25,26,27. It is seen that, for the pure TNO nanosheets, two core levels of Ti 2p are assigned to Ti 2p1/2 (465.1 eV) and Ti 2p3/2 (459.4 eV), respectively. While the Ti peaks of TNO−x@C3 shift left as compared with the pure TNO nanosheets, demonstrating the existence of Ti3+ in the TNO−x@C3 (Supplementary Fig. 9e). In the meantime, Nb 3d spectra also show two characteristic core levels for the pure TNO nanosheets, indexed well into Nb 3d5/2 (207.6 eV) and Nb 3d3/2 (210.4 eV), respectively. While lower binding-energy centered at 210.1 eV (Nb 3d3/2) and 207.5 eV (Nb 3d5/2) are noticed for the TNO−x@C3 composite, demonstrating more Nb4+ ions in the TNO−x@C3 sample (Supplementary Fig. 9f). In short, the presence of Ti3+ and Nb4+ further verifies the presence of oxygen deficiency induced by such a carbon engineering strategy.
In addition, X-ray absorption near-edge structure (XANES) analysis was employed to investigate the defective chemistry. Figure 2e shows the Ti L-edge XANES spectra, where four peaks centered at maxima over the energy range belong to L3t2g, L3eg, L2t2g, and L2eg, respectively. The lowered peak intensity of t2g in TNO−x@C3 indicates that the Ti in TNO−x@C3 sample has a lower valence state due to partially occupied electronic states of eg and t2g at the surface region. The above difference is attributed to the presence of oxygen deficiencies, which can cause loss of long-range order28. Meanwhile, Fig. 2f presents the normalized Nb L2 and L3-edge XANES absorption spectra of the two samples, matching well with the transition of 2p1/2→nd and 2p3/2→nd, respectively. Notice that the TNO−x@C3 shows lower peak intensity, suggesting a number decrease of Nb 3d holes as a result of the generated oxygen deficiencies23,29. Moreover, as shown in Fig. 3a, b, the Ti K-edge spectra of TNO−x@C3 exhibits similar characteristic compared with the TNO phase. Nevertheless, the TNO−x@C3 sample displays lower valance state according to left shift of absorption edge position, implying the presence of abundant oxygen deficiencies. In order to deepen the understanding of the electronic state and oxygen deficiencies, XAFS spectra of Nb K-edge were tested for both of the samples. The XANES of the TNO−x@C3 shows a smaller energy of the absorption edge (Fig. 3c, d), consistent with the XPS results. Figure 3e, f exhibits the corresponding R space curves of k2 [χ (k)] weighted Fourier transform spectra30,31. The peaks centered at 0–2 Å in these TNO samples belong to Nb–O bond, and another peak at 3–4 Å is attributed to Nb–Nb or Nb–Ti vectors23,32. It is worth noting that the TNO−x@C3 displays lower intensity in the Nb–O bond, indicating the lower oxygen coordination number and more oxygen deficiencies. The above results support each other to demonstrate that such boundary carbon engineering could not only provide scalable carbon layer, but also introduce oxygen deficiencies in the TNO.
First-principle calculations of TNO
To illustrate the influence of oxygen vacancy on the properties of TNO, the first-principle calculations were employed. As shown in Supplementary Fig. 10, there are five main cases of oxygen vacancies: oxygen vacancy between Ti and Nb atoms (TNO−x (O:Ti–Nb)), between Nb and Nb atoms (TNO−x (O:Nb–Nb)), between Nb, Nb, and Nb atoms (TNO−x (O:Nb–Nb–Nb)), between Nb, Ti, and Nb atoms (TNO−x (O:Nb–Ti–Nb)), between Ti, Nb, and Ti atoms (TNO−x (O:Ti–Nb–Ti)). Their crystal structures are optimized and the corresponding lattice parameters and energies are listed in Supplementary Table 1. Note that the TNO−x (O:Nb–Nb) has relatively low energies than the others, demonstrating that the TNO−x (O:Nb–Nb) is more stable and the oxygen atom is prone to lose at the position. Moreover, the total density of states and partial density of states were calculated (Fig. 4a, b and Supplementary Fig. 11). For the valence band of the perfect TNO, it is found that the strong hybridizations between Ni3d-O2p and Ti3d-O2p are revealed by their obvious overlaps and consistent amplitudes33. Impressively, the electron conductivity can also be significantly affected by oxygen vacancy. For the defective TNO−x (O:Ti–Nb) and TNO−x (O:Nb–Nb), the Fermi level transforms from the top of the valence band of the perfect crystal to the bottom of the conduction band of defective TNO−x, which can greatly improve the intrinsic electronic conductivity of electrode material. For the defective TNO−x (O:Nb–Nb–Nb), TNO−x (O:Nb–Ti–Nb), and TNO−x (O:Ti–Nb–Ti), not only the Fermi level moves toward high-energy direction, but also the impurity levels appear between the valence and conduction band. And the composition of the impurity level is heavily dependent on the oxygen vacancy position. Due to the existence of the impurity levels, the electronic conductivity of the defective TNO−x can be greatly enhanced. In addition, it could be seen that the partial charge density of the perfect crystal has a strong locality near the Fermi plane, while the partial charge density of the crystal with oxygen vacancy is relatively dispersed. This further indicates that oxygen deficiency can improve electrical conductivity (Supplementary Fig. 12). Moreover, the Li ion diffusion pathways and energy barrier for TNO and TNO−x (O:Nb–Nb) were further explored using nudged elastic-band (NEB) method. Herein, the defective TNO−x (O:Nb–Nb) was chosen as a case due to lowest formation energy. For simplification, the smallest crystal structure unit was used in the NEB calculation process. As shown in Fig. 4e, f, the Li ion diffusion pathways of TNO and TNO−x (O:Nb–Nb) are described, respectively. The initial site of Li ion is the lowest energy oxygen deficiency site and the final is the lowest energy interstitial site. Their corresponding energy barriers are shown in Fig. 4c, d. It could be seen that the energy barrier of the pure TNO is only 0.91 eV, while the energy barrier of the TNO−x (O:Nb–Nb) reduces to 0.71 eV. This indicates that the Li ion is easier to migrate in defective TNO−x (O:Nb–Nb) than the pure TNO. Based on the above results, enhanced electrical conductivity and ionic transfer are ensured for the TNO−x@C3 composites and better Li ion storage performance can be anticipated.
Electrochemical performance of TNO−x@C3 composites
The electrochemical performance was firstly monitored by charge–discharge tests in the voltage window of 1.0–2.5 V (Fig. 5a). The discharge specific capacity of TNO−x@C3 is 280 mA h g−1, higher than that of pure TNO electrode (217 mA h g−1). The improved electrochemical performance was also verified by electrochemical impedance spectrum (EIS) test. The TNO−x@C3 electrode presents smaller charge-transfer resistance and ohmic resistance (Fig. 5b), indicating that the oxygen deficiencies and carbon layer can facilitate charge transfer and boost reaction kinetics. Apparently, the TNO−x@C3 electrode exhibits superior high-rate performance with large capacities of 253 mA h g−1, 226 mA h g−1, and 197 mA h g−1 at 5 C, 10 C, and 20 C (Fig. 5c), respectively, superior to those of the TNO electrode (195 mA h g−1 at 5 C, 162 mA h g−1 at 10 C, and 136 mA h g−1 at 20 C) (Supplementary Fig. 13c). Note that the introduction of abundant oxygen deficiencies and high-quality carbon coating can enhance electrochemical rate performance because of greatly improved intrinsic conductivity and integrated conductive network. Meanwhile, the obtained Ip (intensity of Nb4+/Nb5+ anodic peak) is plotted as a function with V1/2 (V is the scan rates) in Fig. 5d and Supplementary Fig. 13a–b, whose slope stands for the Li+ diffusion coefficient. Obviously, the TNO−x@C3 electrode displays a steep slope with 1.98 times larger than that of the pure TNO electrode, suggesting larger Li+ diffusion coefficient. More importantly, long-term durability is achieved for the TNO−x@C3 electrode (Fig. 5e), which displays a discharge capacity of 223 mA h g−1 at 10 C with a capacity retention of 98.7% over 500 cycles. In contrast, the TNO counterpart only shows a capacity of 140 mA h g−1 (capacity retention of 85.9% over 500 cycles). The enhanced rate performance and long cycle life of TNO−x@C3 electrode arise from the synergistic effects between the oxygen deficiencies existence and controllable boundary carbon coating.
In addition, a deeper understanding of superior lithium storage performance by synergistic engineering of carbon and deficiency was investigated through ex situ HEXRD to detect the lattice parameters of the pure and TNO−x@C3 (Fig. 6a, b). The nanoscale nature of both materials gives rise to a significant line broadening of the diffraction peaks, therefore Lebail method with size model of spherical harmonics was adopted for the refinements of the XRD patterns. All the Bragg peaks could be successfully described with the monoclinic ReO3 shear structure (space group, C2/m), indicating that the carbon will not change the long-range coherence of TNO framework4. Nevertheless, a remarkable lattice expansion is revealed for the TNO−x@C3 sample in contrast with the pure TNO (Supplementary Table 2). This could be ascribed to the existence of Ti3+ and Nb4+ (with larger ion-radiuses than Ti4+ and Nb5+) that are reduced by the oxygen vacancies7,34. The increased lattice parameters of TNO−x@C3 might further indicate the probable missing location of lattice oxygen is in the Nb–Nb site (TNO−x (O:Nb–Nb)) according to the consistent results of HEXRD and Density functional theory (DFT) calculations. The lattice expansion further suggests that the TNO−x@C3 electrode is beneficial for Li ions transfer. In the meantime, in situ synchrotron HEXRD measurements were also performed on both pure TNO and TNO−x@C3 within the first discharge–charge cycle. From the 2D contour plots of the XRD patterns (Fig. 6c, d), remarkably, a striking shift of all the Bragg peaks is observed for the pure TNO, while the peak shifting for the TNO−x@C3 is less obvious. In addition, the pure TNO patterns also show a more anisotropic feature in contrast with TNO−x@C3. Two typical groups of the peak profiles are presented to detail these behaviors. Accordingly, it could be speculated that the lattice of the TNO−x@C3 experiences a moderate structural change over cycling due to modulation of synergistic engineering of carbon and deficiency. The lattice evolutions of both materials are extracted from the in situ XRD patterns for a more specific view. For the pure TNO, four structural transitions occur continuously as the lithium ions embed into the framework, leading to five monoclinic structures (referred as M1–M5) over the whole discharging stage (Fig. 7a). These transitions are fingerprinted by the abruptly evolutive breaks of the axes, as it signals the potential barriers to be overcome35,36. In detail, the transitions from M1 to M4 (3.0–1.5 V) are irreversible, during which the lattice parameters exhibit a nonmonotonic dependence on lithium content. This period could be recognized as the activation process, i.e., the rearrangements of host-atoms to tolerate Li-insertion, which could inevitably induce mechanical fractures that deteriorate reversible capacity and cyclic kinetics. As for the TNO−x@C3, only one structural transition between two monoclinic structures (Mc1 and Mc2) is observed upon discharging, and just as importantly, the lattice anisotropy is also significantly weakened (Fig. 7b) compared with the pure TNO material. This provides evidence that the harmful activation of TNO could be efficiently inhibited through building these carbon-coated boundaries. In addition, the subsequent delithiation leads to a coupled expansion of a-/c-axis and an independent contraction of b-axis for both materials, indicating that the Li+ diffusion path could be along b-direction. Notably, an obvious weakening of the lattice changes along all directions is observed for the TNO−x@C3. For these two materials, this solid-solution reaction is almost reversible, so the weakening of the periodic structural fluctuation in the TNO−x@C3 could reduce the repeated lattice strain and eventually lead to a significant improvement on the cycling performance. To better understand the structural features of TNO−x@C3 electrodes, ex situ electrochemical dilatometry was employed. Supplementary Fig. 14 presents the electrode thickness variation of TNO−x@C3 and TNO during the first galvanostatic discharge/charge cycle according to the SEM results (Supplementary Fig. 15). Obviously, discharge and charge processes are accompanied with a thickness increase and then decrease for two electrodes, respectively. In agreement with the results of in situ XRD analysis above, the TNO−x@C3 electrode shows a lower expansion rate than TNO electrode, mainly due to the buffer function of boundary carbon coating. In all, from the structural point of view, the origin of the enhanced cycling performance of TNO−x@C3 is twofold: the inhibition of the activation process and the weakening of the cyclic structural change. This could be explained by the stability of the carbon-coated boundaries, which constrains the internal grains from complex phase transitions upon the initial lithiation and severe lattice change induced from the solid-solution reaction.
To summarize, we have verified a universal and controllable low-temperature engineering of carbon and deficiency down to primary-grain level to achieve fast charging/discharging electrode materials with conformal and thickness-adjustable boundary carbon. Impressively, relying on such exquisite boundary architecture, significantly improved electron transport and enlarged Li+ diffusion path, shortened activation process and better structural stability are readily realized in the electrode materials due to the regulation of oxygen vacancy and weakened lattice dynamical anisotropy. As a result, the enhanced high-rate energy storage performance has been triggered in the TNO−x@C3 electrodes, which show superior rate capability (197 mA h g−1 at 20 C, corresponding to 3 min charge time) and remarkable cycling durability in lithium ion storage, much better than other counterparts (Supplementary Table 3). Most importantly, our developed engineering of carbon and deficiency is versatile and demonstrated to be applicable in a series of metal oxides systems (TNO−x@C, Nb2O5−x@C, TiO2−x@C, and ZnO−x@C) with adjustable structure, morphology, and composition. Our work reveals a ground-breaking method in the boundary carbon design/decoration of composite materials for electrochemical energy storage.
Synthesis of TNO−x@C3 composites
First, the 3D hierarchical porous pure TNO were fabricated via a facile solvothermal method. The puffed rice was annealed at 800 °C for 3 h in Ar to obtain PRC as the sacrificial carbon template. Then, 0.56 g Ti–(OC3H7)4 and 2.7 g NbCl5 were added into 60 mL ethanol to form the homogeneous solution after stirring. Then, the above solution was transferred into a Teflon-linked steel autoclave with the PRC immersed into it, and kept at 200 °C for 10 h. After that, the as-obtained materials were annealed in air at 800 °C for 2 h to form pure 3D hierarchical porous TNO. Finally, the 3D hierarchical porous TNO powder was annealed at 400 °C for 1 h in C2H2 atmosphere to obtain TNO−x@C3 composites. For comparison, the TNO−x@C1 and TNO−x@C5 composites were obtained by annealing at 350 °C and 450 °C for 1 h in C2H2 atmosphere, respectively.
The morphologies and microstructures of all samples were monitored by SEM (Hitachi S-4800) and TEM-HRTEM (JEOL 2100F at 200 kV) and spherical aberration-corrected scanning transmission electron microscopy (JEOL 2100F). XRD (Rigaku D/MAX 2550/PC) patterns were recorded in the range of 10–80°. Raman spectra were measured under laser excitation at 514 nm (LabRam HR UV). TG measurement was carried out by using Netzsch STA 449C thermal analyser. The chemical components and valence state were conducted by XPS (eSCALAB250Xi). XANES spectra (Ti K-edge and Nb L-edge) were collected at the 4W7A beamline station in Beijing Synchrotron Radiation Facility (BSRF, operated at 2.5 GeV with a maximum current of 250 mA) of China. The spectra were performed in the total electron yield (TEY) mode and the sample drain current was collected with a base pressure under than 5 × 10−8 Pa. X-ray absorption fine structure (XAFS) spectra (Nb K-edge) were carried out at the BL14W1 beamline station in Shanghai Synchrotron Radiation Facility (SSRF, operated at 3.5 GeV with a maximum current of 230 mA), China. The synchrotron beamline was monochromatized with Si (111) and Si (311) double-crystal monochromators to reduce the harmonic component. The data were collected at room temperature in fluorescence mode and analyzed according to the standard procedures using the Demeter software packages (University of Chicago). XANES spectra (Ti L-edge) were measured at beamline station BL12B in National Synchrotron Radiation Laboratory (NSRL, operated at 800 MeV with a maximum current of 300 mA) of China. The samples were placed on double-sided carbon tape for X-ray spectroscopy and all spectra were obtained with the TEY mode37. The “a.u.” was the abbreviation for “arbitrary units”.
Measurements of electrochemical performance
For the electrochemical performance evaluation, the working electrode was prepared by mixing TNO or TNO−x@C3, Super P conductive carbon, and polyvinylidene fluoride in an 80:10:10 weight ratio, the lithium foil and microporous polypropylene film (Celgard, 2300) were used as counter electrode and separator, respectively. The electrochemical properties were tested in CR2025-type coin cells using 1.0 M LiPF6 in acetylene carbonate/dimethyl carbonate (EC/DEC, 1:1, by volume) as the electrolyte. EIS and cyclic voltammetry (CV) curves were conducted on a CHI 660E electrochemical workstation (CH Instruments Inc., Shanghai). CV tests were carried out from 1.0 to 2.5 V at different scan rates. For EIS, the amplitude of the sine perturbation signal was 5 mV, and the frequency was scanned from the highest (100 kHz) to the lowest (10 mHz). The galvanostatic charge/discharge measurement was performed on a NEWARE battery testing system between cutoff voltages of 1.0–2.5 V (vs. Li/Li+) at different current densities at room temperature. The loading amount of active material was about 2 mg cm−2 (1C = 396 mA g−1).
Collection and analysis of in situ synchrotron XRD
The in situ XRD measurements were performed using 11-ID-C beamline at Advanced Photon Source (APS) of Argonne National Laboratory, with the X-ray wavelength of 0.1173 Å. Si (113) single crystal was used as monochromator for an X-ray beam at 105.7 keV. In a typical in situ collection, the coin cell with TNO or TNO−x anode was operated with a constant current of 0.075 C. A single XRD pattern was obtained using a time period of 120 s35. The 2D diffraction patterns were collected in the transmission geometry with a Perkin-Elmer detector. The sample-to-detector distance, detector tilt angles and the instrumental resolution function were calibrated with a standard sample of CeO2. The integration and calibration of the 2D patterns were performed with the Fit2D software, and the lattice parameters were extracted from the integrated XRD patterns using Fullprof software. For the Lebail method, the backgrounds were subtracted by linear interpolation and the peak shapes were described using Thompson–Cox–Hastings profile function to separate the Gaussian and Lorentzian contributions to the Bragg peaks34,38. An anisotropic Lorentzian size broadening (spherical harmonics) was employed to describe the microstructure of the nanoscale TNO materials.
DFT calculations were carried out to investigate the electronic structure by using the first-principle and projector-augmented wave39 as implemented in Vienna ab initio simulation package40. The spin-polarized generalized gradient approximation in the form of Perdew–Burke–Ernzerhof formulation41 was employed for the correlation functional and electronic exchange. The plane-wave energy cutoff was set to 500 eV. The convergence tolerances and Hellmann–Feynman force on each atom were 0.01 eV Å−1 and 10−5 eV for maximum, respectively. Brillouin-zone integration was modeled by a periodic scheme 3 × 3 × 3 k-point mesh, where the lattice vectors together with unit cell shape and size and atomic coordinates were relaxed33. The Li ion diffusion pathways calculations were employed using the climbing image nudged elastic-band method.
The data that support the findings of this study are available from the authors upon reasonable request, see author contributions for specific datasets.
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This work is supported by National Natural Science Foundation of China (Grant No. 51772272 and 51728204), National youth talent support program of China, Natural Science Funds for Distinguished Young Scholar of Zhejiang Province (Grant No. LR20E020001), National youth talent support program of China, Natural Science Funds for Distinguished Young Scholar of Zhejiang Province (Grant No. LR20E020001), Fundamental Research Funds for the Central Universities (Grant No. 2018QNA4011), Qianjiang Talents Plan D (QJD1602029), Startup Foundation for Hundred-Talent Program of Zhejiang University, Key Research and Development Program of Hainan Province (ZDYF2017166). This study was partially sponsored by the project of Fundamental Investigation of Phase Transformative Materials for Energy Application (Project No. 9610399) supported by the City University of Hong Kong and was partially supported by the Shenzhen Science and Technology Innovation Committee (Grant No. R-IND14701). We also appreciate the Photoemission Endstations (BL10B) of Hefei National Synchrotron Radiation Laboratory (NSRL), soft x-ray microscope at beam BL07W in NSRL, 4W7A beamline of the Beijing Synchrotron Radiation Facility (BSRF) and BL14W1 beamline of the Shanghai Synchrotron Radiation Facility (SSRF) for help in XANES and EXAFS characterizations. This research also used resources of the Advanced Photon Source, the US Department of Energy (DOE) Office of Science User Facility operated for the DOE Office of Science by Argonne National Laboratory under Contract No. DE-AC02-06CH11357.
The authors declare no competing interests.
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Deng, S., Zhu, H., Wang, G. et al. Boosting fast energy storage by synergistic engineering of carbon and deficiency. Nat Commun 11, 132 (2020). https://doi.org/10.1038/s41467-019-13945-1
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