1. Introduction

Search of electrode materials capable of increasing the energy capacity of LIBs is an actual topic of contemporary research. Silicon, a material with extremely high specific gravimetric capacity, is considered to be the most promising for fabrication of LIB negative electrodes. Problems that arise in the practical application of Si [1,2,3,4,5,6,7] are generally solved by using it in the form of nanosized particles and forming silicon-carbon composites [4]. Coating the silicon particle surface with a layer of carbon makes it possible to increase the capacity and improve rate capability of the electrodes by reducing their electrical resistance. In addition, an increase in the Coulombic efficiency and cyclic life of the electrode is achieved due to the shift of the solid electrolyte interphase (SEI) formation region to the outer carbon shell of silicon particles.

Recently, we have proposed a new technology of Si-C nanocomposite formation by a low temperature (~600 °C) reduction of carbon by silicon from its fluorides. A powder of solid-phase carbon monofluoride mixed with a powder of nanodispersed silicon was used as a distributed source of gaseous carbon fluorides [8,9,10]. A shell of low ordered carbon is formed around Si nanoparticles after annealing of the mixture. This carbon shell is conjugated with other shells of neighboring particles into a continuous conductive network throughout the entire volume of the resulting composite. Since the reduction of carbon by silicon proceeded with the participation of gaseous compounds and required the removal of the gaseous byproduct (SiF₄), the resulting carbon material gained a well-developed loose porous structure. Such a structure provides efficient accommodation for Si particles during cyclic volume changes in the processes of lithiation–delithiation of LIB anodes. At the same time, the high dispersion of the carbon component of the composites reduces its electrical conductivity, and the large specific surface area of carbon particles causes significant irreversible losses during the formation of SEI. Therefore, the problem of increasing the degree of graphitization of low ordered carbon in such composites becomes topical [11]. It is known that graphitization of amorphous carbon occurs at very high temperatures >1700 °C [12]. These temperatures are unacceptable in the case of Si-C composites due to the formation of cubic silicon carbide β-SiC at T~1100 °C. The forming carbide does not demonstrate a noticeable capacity with respect to Li [13].

In the present work, we attempted to order the structure of the carbon coating, while avoiding its transformation into Si-C, by lowering the carbon graphitization temperature in the presence of catalysts. In contact with transition metals such as Fe, Co and Ni, the graphitization temperature of amorphous carbon decreases below 1000 °C [14,15,16,17]. Here we studied the influence of Ni on the composition, structure and electrochemical performance of Si-C composites heat treated in the 500–1100 °C temperature range.

2. Materials and Methods

The synthesis of composites was carried out in two stages. The precursors for this process were Si nanopowder (Hongwu Nanometer, China) with an average particle size of 40 nm and fluorocarbon powder CF_x, where x = 0.82 (Halo Polymer, Russia). Powders taken in the weight ratio 30 wt.% Si + 70 wt.% CF_0.82 were thoroughly mixed and ground in an agate mortar. Pellets 10 mm in diameter and ~650 µm thick were prepared from the resulting mixture by cold dry compaction under a pressure of 180 MPa. The samples were annealed in a quasi-closed volume of graphite cassettes. The cassettes were placed in a muffle furnace with a quartz tube purged with high-purity argon (99.998%) and were heated to 400 °C. Then the temperature was increased at a rate of 3.3 °C/min up to 800 °C and maintained at this level for 20 min, followed by slow cooling in an Ar atmosphere down to 500 °C. The composite samples obtained as a result of such annealing are referred to in the text as “as carbonized”. At the second stage, part of the annealed pellets was saturated by a 6 wt.% (Ni(NO₃)₂·6H₂O) alcohol solution and dried at 60 °C until the solvent and bound water were completely removed. The saturation was carried out so that the final increase in the pellet weight was ~60 wt.%. After that, the Ni-containing and control pellets were loaded into a tube filled with Ar and heated to 200 °C, followed by an increase in temperature at a rate of 3.3 °C /min to the target temperature in the 500–1100 °C range, maintained for 2 h, and slowly unloaded for 10 min.

Scanning electron microscopy (SEM) and energy dispersive X-ray spectroscopy (EDS) of the obtained composites were carried out using an FEI Quanta 200 scanning electron microscope (FEI company, Hillsboro, OR, USA). X-ray diffraction (XRD) study was carried out using a Rigaku Corporation SmartLab 3 diffractometer (Rigaku Corporation, Japan) equipped with a copper anode and an Ni-filter (λ = 0.1542 nm). Diffraction patterns were recorded by scanning at 5–80° intervals 2θ with 0.01° step. The phase analysis was created by using the ICDD PDF-2 database. Peak fitting was carried out using the Fityk program [18]. Reflexes suitable for analysis were in the 2θ range of 25–65° angles. The reflexes were approximated by the Pearson 7 function. Crystallite sizes were calculated using the Scherrer equation:

d = Kλ/(β cos θ)(1)

The analysis of structural changes in the low ordered carbon shell of Si-C composites was carried out on the basis of the obtained Raman spectra. Raman scattering experiments were carried out on a HORIBA-JOBIN-YVON MRS 320 modular micro-Raman spectrometer(Horiba Scientific, Kyoto, Japan) equipped with an OLIMPUS BX41 microscope (Olympus, Tokyo, Japan). For excitation, a He-Ne laser with a wavelength of 632.81 nm was used. The radiation power did not exceed 2 mW. The scattered light was separated from the background of the excitation light by a step-filter and was recorded by a CCD receiver. The experiments were carried out at room temperature. To fit the spectra, the Fityk program was used.

Thermodynamic calculations were made using the IVTANTERMO program package version 30-3 to estimate the temperatures of the start of the decomposition reactions of nickel nitrate and the interaction of nickel oxide with carbon [19].

For the fabrication of electrodes from the obtained pellets, their thickness was reduced by grinding to 100 μm. The mass of the samples was 1–3 mg after grinding. After that, the samples were glued onto copper foil using a suspension based on polyvinylidene fluoride (PVDF), highly split graphite and NMP (N-methylpyrrolidone).

The electrochemical measurements of the samples were performed with coin cells CR2032 using lithium metal as the counter electrode. The electrolyte was Tinci TC-E918 (Guangzhou Tinci Materials Technology Co, LTD, GuangZhou, China), which was a 1 M solution of LiPF6 in a mixture of EC/PC/DEC/EMC/PA (ethylene carbonate, propylene carbonate, diethyl carbonate, ethyl methyl carbonate, propyl acetate). The cells were galvanostatically charged and discharged at various current densities ranging between 10 mV and 2 V (vs. Li/Li⁺) on the Neware CT 3008 W–5 V 10 mA testing system (Neware, Hong Kong, China).

3. Results and Discussion

3.1. Formation of Composites

Formation of the initial Si-C nanocomposites begins with the disproportionation of solid-state fluorocarbon and the release into the gas phase of lighter fluorocarbon molecules. These molecules interact with the surface of Si particles with formation of carbon and gaseous SiF₄. The resulting carbon forms a layer of gas-permeable amorphous material around silicon particles. However, in the amorphous carbon the association of atoms immediately begins to develop, leading to the emergence of fragments consisting of graphene networks from sp²-hybridized atoms, and their mutual ordering occurs. This process is caused by the tendency of carbon to go into the most thermodynamically stable state at normal pressure. The size and density of the graphite-like nanoparticles depend on initial density of carbon atoms reduced on the silicon surface, temperature, and duration of the heat treatment. In addition, a noticeable amount of free carbon (~20% of the total mass of carbon) remains in the solid phase after the decomposition of non-stoichiometric carbon monofluoride. This carbon retains residual fluorine and, probably, has a higher degree of graphitization compared to carbon formed during the chemical interaction of gaseous fluorides with silicon [9,10]. The overall reaction describing these processes can be represented as:

CF_x + Si = 4/xC + SiF₄(2)

Under the condition of a super stoichiometric excess of silicon necessary to obtain a composite, the mass balance of substances participating in Reaction (1) for x = 0.82 can be written as follows:

r CF_0.82 +(100 − r)Si = 0.773r SiF₄ + 0.435r C + (100 − 1.208r) Si(3)

We used r = 70% for the composition of the initial mixture, then the concentration of C and Si in the resulting composite should be 66 wt.% (82 at.%) and 34 wt.% (18 at.%), respectively, according to Equation (3). The correctness of this estimation was confirmed by the actual reduction in the weight of the pellets during annealing (54.8%) in comparison with the calculated value (54.1%).

Nickel oxide formation and oxidation of silicon surface by released oxygen and nitrogen dioxide are the first chemical processes developing at increasing temperature after introduction of nickel nitrate into the composite. (According to thermodynamic evaluation, decomposition of nickel nitrate should start at T~300 °C). Nickel oxide can be reduced by both carbon and silicon to metallic nickel by further increasing the temperature in an inert atmosphere. Then nickel interacts with silicon to form the corresponding silicides. It is estimated that the reduction of nickel by carbon can start at T~500 °C. The interaction of passivating SiO₂ films on the surface of silicon particles with NiO to form nickel silicate may be a side process that contributes to the destruction of the SiO₂ films. Nickel can be reduced with carbon or silicon from its silicate at higher temperatures. The initial chemical processes occurring during annealing of Ni-containing Si-C composites can be roughly represented by the following reactions:

2Ni(NO₃)₂ = 2NiO + 4 NO₂ + O₂(4)

Si + 2NO₂ = SiO₂ + 2NO(5)

SiO₂ + NiO = NiSiO₃(6)

2NiO + C = 2Ni + CO₂(7)

2NiO + Si =2Ni + SiO₂(8)

2NiSiO₃ + C = 2Ni + CO₂ +2SiO₂(9)

2Ni + Si = Ni₂Si(10)

It is not difficult to calculate the ratio of atomic concentrations of the main elements (Ni, Si and C) involved in the chemical transformations averaged over the volume of the annealed material. We found that the relative amount of elements is the following: Ni/Si~0.27; Ni/C~0.06, mole fraction of Ni relative to the total amount of Si and C~8.7 at.%.

3.2. Scanning Electron Microscopy

The SEM image in Figure 1 demonstrates heterogeneous structure of a sample annealed at 1100 °C.

EDS showed the following values for the averaged composition of particles coming to the surface: 32 at.% Ni; 18.8 at.% Si; 44.9 at.% C; 0.6 at.% F; 3.5 at.% O. We registered a significant excess of the nickel content in the surface layer of the sintered composite in relation to other elements as compared with the calculated values. This observation can be explained by the fact that the nickel nitrate was initially concentrated in their near-surface layer, as a result of drying the pellets soaked in a salt solution. This spatial distribution of salt is the result of slow evaporation of the solvent from the porous material. The salt begins to crystallize on the outer open surface of the sample as the solvent evaporates. Diffusion flows emerge in the pore channels of both solvent and dissolved substance from the volume to the open surface if a wetting layer exists. The wetting layer is a supersaturated solution on the surface of growing salt crystals. We can also assume that after annealing the main nickel-containing phase on its surface was nickel silicide Ni₂Si based on the ratio Ni/Si = 1.7 for the surface layer of the pellet. The detected elemental composition of the surface layer of the pellets remained practically the same for all annealing temperatures starting from 800 °C. Homogeneous distribution of elements at their practically unchanged ratio (Figure 2) was observed in the volume of samples, regardless of the annealing temperature. According to EDS data, the total Ni content in the volume of pellets was ~5.5 at.%, Si~10.8 at.%, C~73.4 at.%. The obtained nickel content satisfactorily agrees with the initial estimation of the total nickel concentration in the sample, taking into account the detected nickel enrichment of the near-surface layer of the annealed pellets. In addition, O and F were detected in the samples, the total content of which decreased when the annealing temperature rose to 1100 °C from 10 to 5.7 at.%, and from 1 to 0.5 at.%, respectively. The presence of fluorine and oxygen can be explained by the above reactions and incomplete disproportionation of carbon monofluoride during the formation of the initial Si-C composite.

3.3. X-ray Diffraction

Figure 3 shows diffraction patterns of pellets that were heat-treated at different temperatures, with Ni and control ones without Ni. For a correct comparison of the peaks shown in Figure 3, Figure 4 and Figure 5 their integral intensities were normalized by dividing by the sample mass, I/m.

The XRD patterns (Figure 3a) show that the reduction of nickel oxide by carbon began at 500 °C and finished above 800 °C (the XRD patterns for 500 and 600 °C are identical, therefore only the pattern for 600 °C is shown). The resulting nickel was already completely transformed into the nickel silicide form δ-Ni₂Si (PDF 48-1339) by this temperature. A further increase in the annealing temperature to 1000 °C resulted in new crystalline nickel silicide phases Ni₃₁Si₁₂ (PDF 24-524) and Ni₃Si (PDF 3-1048) containing more nickel. This seemed surprising, taking into account the significant excess of silicon over nickel in the system. It is worth noting that the formation of silicon carbide β-SiC (PDF 2-1050) occurred as early as 800 °C. Whereas in the control Si-C composites annealed at the same temperature as composites containing nickel, that β-SiC was formed at higher temperature 1100 °C (Figure 3b). A comparison of XRD patterns of samples with and without Ni formed at 900 °C is presented in Figure 4. It should be noted, that XRD patterns of control and as carbonized samples showed a halo in the 15–25° region, which decreased in the nickel-containing samples. It can be assumed that this halo is caused by amorphous carbon [20]. The peaks at 2θ = 26° and 40° (both seen in Figure 3b) are probably due to graphite-like carbon (PDF 12-212), which emerged initially due to disproportionation of CF_x and due to subsequently ordering of the carbon structure.

Estimation of crystallite size of chemically stable phases of nickel silicides and silicon carbide formed during the annealing show that along with the total phase content (Figure 5) the particle size increases as the annealing temperature grows (Figure 6). We should especially note the unexpected tendency for a successive increase in the relative concentration of the silicide phases with a higher nickel content (Ni₂Si → Ni₃₁Si₁₂ → Ni₃Si) as the annealing temperature increases, despite the significant excess of silicon over nickel in the initial material. This behavior can only be explained by the catalytic effect of nickel atoms on carbon atoms, which results in the formation of silicon carbide. This process occurs, indirectly, through nickel silicides Ni₂Si and Ni₃₁Si₁₂. That is, in the temperature range, when the presence of direct contact of carbon with silicon particles does not yet lead to the formation of SiC, the contact of previously formed Ni₂Si particles with carbon led to the formation of silicon carbide:

3Ni₂Si + C = 2Ni₃Si + SiC(11)

As long as the concentration of free silicon in the composite remained high enough, the resulting silicide with a higher nickel content was transferred back to the original one:

2Ni₃Si + Si = 3Ni₂Si(12)

However, when free silicon had been exhausted to form SiC, there was rapid accumulation of silicide with maximum nickel content, which correlates with the data shown in Figure 5. Apparently, activation of carbon atoms occures in the area of their contact with Ni-containing particles in the processes under consideration, as well as in the long-studied processes of graphitization of amorphous carbon in the presence of nickel, iron and other transition d-elements [14]. The reason for this effect should be sought in the exchange of valence electrons on the occupied orbitals of carbon atoms with the vacant d-orbitals of nickel atoms that are part of the silicides.

3.4. Raman Scattering

Figure 7 shows Raman spectra of the nickel-containing sample and the control sample annealed at T = 800 °C. For the Ni-containing sample, silicon carbide peaks due to TO and LO phonons were observed. Fitting their contour using the Pearson 7A function showed that the maximum corresponds to frequencies 782 and 961 cm⁻¹, and the FWHM widths are 11 and 10 cm⁻¹, respectively. It should be noted that these frequencies are shifted to lower energies relative to the position of the peaks in bulk β-SiC (796 and 972 cm⁻¹) [21], which may be due either to stacking fault defects or to quantum confinement effects in nanoscale crystals that shift the characteristic frequencies of phonons [22]. Characteristic bands of nanocrystalline graphite [23,24] were observed throughout the temperature range for the samples with Ni and for the control samples. The first-order spectrum in the 1000–1700 cm⁻¹ range was represented by two peaks, D and G. In some samples the G peak had a high-energy shoulder D₂ at frequency 1615 cm⁻¹ (Figure 8). The second-order spectrum detected a 2D peak at =2650 cm⁻¹, often of small amplitude, and sometimes a D + D₂ peak at 2900 cm⁻¹ was observed. Band G is associated with the valence vibrations of sp²-hybridized carbon atoms in the plane of the graphene layer. D is due to vibrations of the aromatic rings as a whole. D mode is forbidden for perfect crystals of graphite and graphene and emerges when the lattice is disordered. According to the ratio of intensities of peaks D and G and their width, one can estimate the degree of graphitization of the carbon material.

Figure 8 shows how the spectrum of first-order carbon modes changes depending on the annealing temperature. A narrowing of the D and G peaks and a change in their relative intensity is seen. Figure 9 shows the height ratio of peaks D and G. It can be seen that in the control samples, the change in the annealing temperature has no noticeable effect on the relative height of the D and G peaks, whereas in the nickel-containing samples, the H_D/H_G ratio decreases with the temperature increase.

The defectiveness of the graphite-like material can also be estimated from the width of the D and G bands measured at their half-height FWHM. The narrowing of these lines indicates a decrease in the number of structural defects [25]. The width of the G peak in the control samples practically does not change and the D peak width decreases only slightly as the temperature increases, while in the nickel-containing samples a narrowing of both peaks can be seen in Figure 10. In [26] it was shown that a decrease in the width of the G peak in nanocrystalline graphite is associated with an increase in the lateral size of graphite clusters L_a, which can be found from the equation

FWHM = 14 + 430/L_a(13)

The calculation shows that an increase in the temperature of the heat treatment of nickel-containing samples from 600 to 1100 °C results in a 4-fold increase in L_a from 7 to 29 nm, while in the control samples it remains unchanged at 7 nm. Thus, analysis of Raman spectroscopy data indicates the catalytic effect of nickel, leading to a more effective graphitization of carbon during low-temperature annealing.

3.5. Electrochemical Characterization

The voltage profiles of the first cycle for samples with Ni and control (without Ni), as well as for as carbonized samples, are shown in Figure 11. In the case of control samples, the annealing temperature did not change the charge-discharge curves, as shown in Figure 11a. They remained practically the same as for the as carbonized sample.

In contrast to the control samples, the electrochemical performance of the nickel-containing samples strongly depends on the annealing temperature (Figure 11b,c). Annealing at 600 °C led to an increase in both the charge and discharge capacities of the electrodes compared to the capacity of the as carbonized electrode. A clearly pronounced plateau at a voltage of U = 0.6 V can be seen on the voltage profile for the first lithiation of the sample annealed at 600 °C (Figure 11b). The plateau dropped out in subsequent cycles (Figure 11c). The presence of nickel oxide in the composition of the material explains the emergence of this region. As was shown in [27,28,29], the plateau at ~0.5 V is due to the reduction of NiO to Ni, accompanied by the formation of amorphous Li₂O, and the electrolyte decomposition to form the SEI layer at the first lithiation

NiO + 2Li⁺ + 2e ↔ Li₂O + Ni(14)

According to the same work, the reverse reaction of nickel oxidation and reduction of Li from its oxide proceeds at voltage > 2 V, which were not used in our cycling tests. Therefore, in our case, Li₂O was an irreversible phase. A decrease of the capacity was observed in the electrode with a further increase in the annealing temperature of nickel-containing samples. The horizontal plateau typical for silicon lithiation dropped out from the charge profile. Shift of the charge curve was observed towards lower voltages. The values of the capacities of the first cycle and the Coulombic efficiency (CE) are presented in Table 1. The table shows that the decrease in the capacity of Ni-containing electrodes annealed at 800 °C and 1100 °C was accompanied by a decrease in their CE from 52.5 to 26.3%, while for the 600 °C Ni-containing sample, CE retained a value close to the as carbonized sample along with an increase in capacity.

The CE increased on subsequent cycles and became constant at 98% (Figure 12a). An increase in the current density (j) of the charge/discharge from 25 to 50 and 100 mA/g led to a drop in the capacity of the electrodes, as shown in Figure 12b. Table 1 shows the drop in capacity relative to the capacity at j = 25 mA/g: ∆Q_50mA/g/Q_25mA/g = (Q₂₅ − Q₅₀)/Q₂₅ and ∆Q_100mA/g/Q_25mA/g = (Q₂₅ − Q₁₀₀)/Q₂₅. Therefore, the best rate capability was demonstrated by the Ni-containing anode treated at 600 °C.

Improvement of the electrochemical performances of Si-C electrodes by saturation of this material by solution of nickel salt and subsequent annealing at T ≤ 600 °C and a sharp degradation at T > 600 °C was due to the different composition of the material. The presence of nickel in the composite apparently leads to an improvement in the electronic conductivity of the composites. As a result, an increase in the capacity and rate capability of the 600 °C Ni electrode was observed compared to the as carbonized electrode. Similar effect was also registered in [30]. The decrease in capacity and rate capability with an increase in the annealing temperature of nickel-containing samples at T > 600 °C were due to the formation of phases of nickel silicides and β-SiC. Consequently, the amount of silicon and carbon, which determine the capacitance and conductivity, decreased.

4. Conclusions

In this work, it was shown that Ni introduced into the Si-C composite was actually capable of increasing the degree of graphitization of carbon. However, its catalytic effect was also found to enhance the reaction on formation of silicon carbide. As a result, heat treatment of Ni-containing composites already at temperatures of about 800 °C led to a sharp decrease in the concentration of silicon, which is responsible for electrode capacity. Thus, the positive effect of Ni on the structure of the carbon component of Si-C composites was completely eliminated by the formation of SiC and Ni_xSi_y, which led to a decrease in the capacity and rate capability of the electrodes.

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Figure 1. SEM image of the surface of a sample with Ni annealed at 1100 °C.

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Figure 2. Cross-section of the sample with Ni annealed at 800 °C: (a) SEM image; (b–f) element distribution maps. (b) Si; (c) Ni; (d) C; (e) O; (f) F.

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Figure 3. XRD patterns of samples annealed at different temperatures: (a) composites with Ni, (b) control without Ni.

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Figure 4. Reflexes in the 2θ range of 15–28° angles for as carbonized sample, control and Ni-containing samples annealed at 900 °C.

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Figure 5. Change in the normalized value of the integral intensity of XRD peaks I/m for a single reflex of each phase, registered in samples with Ni: (a) Si 2θ =28.4°; (b) NiO 2θ = 37.3°; Ni 2θ = 44.5°; (c) – δ-Ni2Si 2θ = 45.5°; Ni31Si12 2θ = 46°; Ni3Si 2θ = 44.7°; (d)–SiC 2θ = 35.6°.

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Figure 6. Temperature dependence of crystallite size for phases: (a) δ-Ni2Si; Ni31Si12; Ni3Si; (b) β-SiC.

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Figure 7. Raman spectra of Ni-containing and control samples annealed at 800 °C.

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Figure 8. First-order Raman spectra of carbon in samples with Ni heat-treated at different temperatures shown in the graph.

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Figure 9. Temperature dependence of D and G peak height ratio HD/HG for nickel-containing and control samples.

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Figure 10. Peak width (FWHM) as a function of heat treatment temperature for nickel-containing and control samples: (a) for D peak, (b) for G peak.

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Figure 11. Voltage profiles of the first (a,b) and fifth (c) cycles for samples annealed at different temperatures.

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Figure 12. Coulombic efficiency (a) and discharge capacity at different currents on the cycle number for as carbonized and nickel-containing electrodes (b).

References

1. Manj, R.Z.A.; Zhang, F.; Rehman, W.U.; Luo, W.; Yang, J. Toward understanding the interaction within Silicon-based anodes for stable lithium storage. Chem. Eng. J.; 2020; 385, 123821. [DOI: https://dx.doi.org/10.1016/j.cej.2019.123821]

2. Obravac, M.N. Review Article Si-alloy negative electrodes for Li-ion batteries. Curr. Opin. Electrochem.; 2018; 9, pp. 8-17. [DOI: https://dx.doi.org/10.1016/j.coelec.2018.02.002]

3. Li, P.; Kim, H.; Myung, S.-T.; Sun, Y.-K. Diverting Exploration of Silicon Anode into Practical Way: A Review Focused on Silicon-Graphite Composite for Lithium Ion Batteries. Energy Storage Mater.; 2021; 35, pp. 550-576. [DOI: https://dx.doi.org/10.1016/j.ensm.2020.11.028]

4. Du, F.-H.; Wang, K.-X.; Chen, J.-S. Strategies to succeed in improving the lithium-ion storage properties of silicon nanomaterials. J. Mater. Chem. A; 2016; 4, pp. 32-50. [DOI: https://dx.doi.org/10.1039/C5TA06962A]

5. Xu, Z.-L.; Liu, X.; Luo, Y.; Zhou, L.; Kim, J.-K. Nanosilicon anodes for high performance rechargeable batteries. Prog. Mater. Sci.; 2017; 90, pp. 1-44. [DOI: https://dx.doi.org/10.1016/j.pmatsci.2017.07.003]

6. Liu, Y.; Zhou, G.; Liu, K.; Cui, Y. Design of Complex Nanomaterials for Energy Storage: Past Success and Future Opportunity. Acc. Chem. Res.; 2017; 50, pp. 2895-2905. [DOI: https://dx.doi.org/10.1021/acs.accounts.7b00450]

7. Liu, X.; Zhu, X.; Pan, D. Solutions for the problems of silicon–carbon anode materials for lithium-ion batteries. R. Soc. Open Sci.; 2018; 5, 172370. [DOI: https://dx.doi.org/10.1098/rsos.172370]

8. Astrova, E.V.; Ulin, V.P.; Parfeneva, A.V.; Voronkov, V.B. Fluorocarbon Carbonization of Nanocrystalline Silicon. Tech. Phys. Lett.; 2019; 45, pp. 664-667. [DOI: https://dx.doi.org/10.1134/S1063785019070022]

9. Astrova, E.; Ulin, V.; Parfeneva, A.; Rumyantsev, A.; Voronkov, V.; Nashchekin, A.; Nevedomskiy, V.; Koshtyal, Y.; Tomkovich, M. Silicon–carbon nanocomposites produced by reduction of carbon monofluoride by silicon. J. Alloys Compd.; 2020; 826, 154242. [DOI: https://dx.doi.org/10.1016/j.jallcom.2020.154242]

10. Lozhkina, D.A.; Astrova, E.V.; Likhachev, A.I.; Parfeneva, A.V.; Rumyantsev, A.M.; Smirnov, A.N.; Ulin, V.P. Silicon Monoxide Carbonized by Fluorocarbon As a Composite Material for Anodes of Lithium-Ion Batteries. Tech. Phys.; 2021; 66, pp. 1228-1240. [DOI: https://dx.doi.org/10.1134/S1063784221090103]

11. Yang, Y.; Ren, J.-G.; Wang, X.; Chui, Y.-S.; Wu, Q.-H.; Chen, X.; Zhang, W. Graphene encapsulated and SiC reinforced silicon nanowires as an anode material for lithium ion batteries. Nanoscale; 2013; 5, pp. 8689-8694. [DOI: https://dx.doi.org/10.1039/c3nr02788k] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23900559]

12. Ubbelonde, A.R.; Lewis, F.A. Graphite and Its Crystal Compounds; Oxford at the Clarendon Press: London, UK, 1960; pp. 9-47.

13. Astrova, E.V.; Parfeneva, A.V.; Rumyantsev, A.M.; Ulin, V.P.; Baidakova, M.V.; Nevedomskiy, V.N.; Nashchekin, A.V. The Effect of Thermal Treatment on Properties of Composite Silicon–Carbon Anodes for Lithium-Ion Batteries. Tech. Phys. Lett.; 2020; 46, pp. 114-117. [DOI: https://dx.doi.org/10.1134/S1063785020020042]

14. Sinclair, R.; Itoh, T.; Chin, R. In Situ TEM Studies of Metal–Carbon Reactions. Microsc. Microanal.; 2002; 8, pp. 288-304. [DOI: https://dx.doi.org/10.1017/S1431927602020226]

15. Wang, K.; Cao, Y.; Wang, X.; Kharel, P.R.; Gibbons, W.; Luo, B.; Gu, Z.; Fan, Q.; Metzger, L. Nickel catalytic graphitized porous carbon as electrode material for high performance supercapacitors. Energy; 2016; 101, pp. 9-15. [DOI: https://dx.doi.org/10.1016/j.energy.2016.01.059]

16. Thompson, E.; Danks, A.E.; Bourgeois, L.; Schnepp, Z. Iron-catalyzed graphitization of biomass. Green Chem.; 2015; 17, pp. 551-556. [DOI: https://dx.doi.org/10.1039/C4GC01673D]

17. Li, S.S.; Wang, J.K.; Zhu, Q.; Zhao, X.W.; Zhang, H.J. Fabrication of Graphitic Carbon Spheres via a Hydrothermal Carbonization Combined Catalytic Graphitization Method Using Cobalt as Catalysts. Solid State Phenom.; 2018; 281, pp. 807-812. [DOI: https://dx.doi.org/10.4028/www.scientific.net/SSP.281.807]

18. Wojdyr, M. Fityk: A general-purpose peak fitting program. J. Appl. Crystallogr.; 2010; 43, pp. 1126-1128. [DOI: https://dx.doi.org/10.1107/S0021889810030499]

19. Gurvich, L.V.; Veits, I.V.; Medvedev, V.A. Termodinamicheskie Svoistva Individual’nykh Veshchestv; Nauka: Moscow, Russia, 1978; Volume 1, Book 1 (In Russian)

20. Destyorini, F.; Irmawati, Y.; Hardiansyah, A.; Widodo, H.; Yahya, I.N.D.; Indayaningsih, N.; Yudianti, R.; Hsu, Y.-I.; Uyama, H. Formation of nanostructured graphitic carbon from coconut waste via low-temperature catalytic graphitisation. Eng. Sci. Technol. Int. J.; 2020; 24, pp. 514-523. [DOI: https://dx.doi.org/10.1016/j.jestch.2020.06.011]

21. Nakashima, S. Harima, H. Raman Investigation of SiC Polytypes. Phys. Stat. Sol. (A); 1997; 162, pp. 39-64. [DOI: https://dx.doi.org/10.1002/1521-396X(199707)162:1<39::AID-PSSA39>3.0.CO;2-L]

22. Qiang, X.; Li, H.; Zhang, Y.; Tian, S.; Wei, J. Synthesis and Raman scattering of SiC nanowires decorated with SiC polycrystalline nanoparticles. Mater. Lett.; 2013; 107, pp. 315-317. [DOI: https://dx.doi.org/10.1016/j.matlet.2013.06.055]

23. Ferrari, A.C.; Robertson, J. Interpretation of Raman spectra of disordered and amorphous carbon. Phys. Rev. B; 2000; 61, 14095. [DOI: https://dx.doi.org/10.1103/PhysRevB.61.14095]

24. Merlen, A.; Buijnsters, J.G.; Pardanaud, C. A Guide to and Review of the Use of Multiwavelength Raman Spectroscopy for Characterizing Defective Aromatic Carbon Solids: From Graphene to Amorphous Carbons. Coatings; 2017; 7, 153. [DOI: https://dx.doi.org/10.3390/coatings7100153]

25. Vinogradov, A.Y.; Grudinkin, S.A.; Besedina, N.A.; Koniakhin, S.V.; Rabchinskii, M.K.; Eidelman, E.D.; Golubev, V.G. Structure and Properties of Thin Graphite-Like Films Produced by Magnetron-Assisted Sputtering. Semiconductors; 2018; 52, pp. 914-920. [DOI: https://dx.doi.org/10.1134/S1063782618070266]

26. Maslova, O.A.; Ammar, M.R.; Guimbretière, G.; Rouzaud, J.-N.; Simon, P. Determination of crystallite size in polished graphitized carbon by Raman spectroscopy. Phys. Rev. B; 2012; 86, 134205. [DOI: https://dx.doi.org/10.1103/PhysRevB.86.134205]

27. Oh, J.H.; Jo, M.S.; Jeong, S.M.; Cho, C.; Kang, Y.C.; Cho, J.S. New synthesis strategy for hollow NiO nanofibers with interstitial nanovoids prepared via electrospinning using camphene for anodes of lithium-ion batteries. J. Ind. Eng. Chem.; 2019; 77, pp. 76-82. [DOI: https://dx.doi.org/10.1016/j.jiec.2019.04.021]

28. Wu, D.; Zhao, W.; Wu, H.; Chen, Z.; Li, H.; Zhang, L.Y. Holey graphene confined hollow nickel oxide nanocrystals for lithium ion storage. Scr. Mater.; 2020; 178, pp. 187-192. [DOI: https://dx.doi.org/10.1016/j.scriptamat.2019.11.015]

29. Zhang, X.; Huang, Q.; Zhang, M.; Li, M.; Hu, J.; Yuan, G. Pine wood-derived hollow carbon fibers@NiO@rGO hybrids as sustainable anodes for lithium-ion batteries. J. Alloys Compd.; 2020; 822, 153718. [DOI: https://dx.doi.org/10.1016/j.jallcom.2020.153718]

30. Chen, Z.; Ye, J.; Qin, R.; Hao, Q.; Xu, C.; Hou, J. Carbon particles modified macroporous Si/Ni composite as an advanced anode material for lithium ion batteries. Int. J. Hydrogen Energy; 2019; 44, pp. 1078-1087. [DOI: https://dx.doi.org/10.1016/j.ijhydene.2018.11.065]