Introduction

In relation to the available anode materials for Li-ion batteries, tin has been shown as one of the best alternatives due to its lithium uptake at low potential and high theoretical capacity (994 mAh g−1 for Li4.4Sn phase) [1]. However, the major problem during formation of LixSny alloys is cyclic volume changes of elementary cell, reaching up to 300 % [2]. That process results in pulverization of the material which leads to the loss of electrical contact between active material and current collector, as well as physical damage of the cell, caused by high strains. The scientists are trying to overcome this issue by developing composites containing Sn and a stress-accommodating phase for instance graphene [35], carbon nanotubes [69], nanofibers [10, 11] or TiO2 nanotubes [12, 13]. Nevertheless, the obtaining process of such materials is complicated and expensive. Therefore, noteworthy idea is development of tin–carbon nanocomposite, in which nanometric tin grains will be encapsulated in a flexible and conductive carbon buffer matrix using low-priced and easily accessible carbon source. Notwithstanding, such nanocomposites are able to provide appropriate electrochemical properties, only if the formed carbon matrix is leak-proof, flexible and optimally porous for Li+ ions permeability, featuring local free space to compensate active material volume changes.

The goal of the present work was leak behaviour testing of two types carbon–tin nanocomposite anode materials using for the first time thermal analysis methods. The comparison of morphological and electrochemical properties of obtained C/Sn anode materials was also discussed.

Experimental

Two series of C/Sn nanocomposites with different origin carbon buffer matrix were obtained. The nanometric precursor of active material (SnO2) was prepared via modified reverse nanoemulsion method (w/o) for both series [14]. First series of the C/Sn anode materials was obtained using the plant polysaccharide—potato starch (PS) as a carbon source. Details of the synthesis were described in our previous papers [15, 16]. Briefly, SnO2 particles were coated by a potato starch in gelatinization process. Then the resulting PS/SnO2 precursor was pyrolysed under argon flow (purity 99.999 %, 3 dm3 h−1) at 800 °C for 6 h. The second series was prepared in the similar way, but the only difference was coating SnO2 by a polymer—poly(N-vinylformamide) modified with 5 mass% of pyromellitic acid (MPNVF) according to a procedure reported in Ref. [17, 18].

Optimal conditions of the pyrolysis were determined by thermogravimetric analysis (TG/DTG) using TGA/SDTA 851e Mettler-Toledo apparatus coupled with quadrupole mass spectrometer (QMS) ThermoStar GSD300T Balzers. The TG instrument was calibrated with indium, zinc and aluminium. Its accuracy is equal to 10−6 g. The mass spectrometer was operated in electron impact mode (EI) using channeltron as a detector. Screening analyses were performed in the selected-ion monitoring (SIM) mode. The following ions’ characteristics of each molecule, such as 17 for OH, NH3, 18 for H2O, 28 for N2, CO, 42 for C3H6, CH2CO and 44 for CO2 were monitored. TG measurements were taken in alumina crucibles under 4.8 dm3 h−1 argon flow, within temperature range 30–1000 °C and heating rate 5 °C min−1. The material’s weight was 10 mg.

The carbon content in the C/Sn composites was determined by the temperature programmed oxidation (TPO) in air atmosphere using TA Instruments SDTA Q600 thermo-analyser. The instrument was calibrated with zinc. The measurements were taken with air flow of 4.8 dm3 h−1 and heating rate of 5 °C min−1, within temperature range 30–1000 °C. 10 mg of sample were used for analysis each time.

In order to describe the melting process of tin in resulting C/Sn composites, the differential scanning calorimetry (DSC) using DSC 821e Mettler-Toledo equipment was performed. The instrument, which accuracy is equal to 10−6 W, was calibrated with indium and zinc. The measurements were conducted in temperature range 150–300 °C under argon flow with scanning rate 5 °C min−1 using aluminium pan. The empty crucible was used as the reference sample. The mass of the material was 10 mg.

Crystal structure of the C/Sn nanopowders was characterized by powder X-ray diffraction (XRD) with BRUKER D2 PHASER using Cu Kα radiation 0.15418 nm. The average size (D XRD) of the tin nanograins was calculated using the Scherrer formula for (200), (101), (220) and (211) reflections.

The specific surface area (S BET) and pore volume (V P) of the composites were evaluated from N2 sorption at −196 °C measured with 3Flex v1.00 (Micromeritics) automated gas adsorption system. Before the analysis, the samples were degassed under vacuum at 350 °C for 24 h using BET (Brunauer–Emmett–Teller) model. The average pore size (D P) was determined by the single point adsorption at p/p 0 = 0.98.

Charge–discharge tests were performed in R2032-type coin cells [Li/Li+/(C/Sn)] using 1 M LiPF6 solution in EC/DEC (1:1). The process of preparation working electrode was featured in previous paper [16]. Assembled cells were tested at a constant current density in the voltage range of 0.01–1.5 V at room temperature using ATLAS 0961 MBI multichannel battery testing system. The battery charging at 0.1 C-rate delivers its nominal evaluated capacity in 10 h.

Results and discussion

The results of carbonization and carboreduction processes of the MPNVF/SnO2 and PS/SnO2 composites precursors performed in argon atmosphere are presented in Fig. 1. The EGA-TG/DTG curves for both samples indicate that the formation of C/Sn composites ends at around 800 °C; therefore, this temperature was selected as the temperature of pyrolysis for both series. However, it should be noticed that the obtainment of a C/Sn compound varies significantly between the materials. For MPNVF series, this process is consisted of four stages. First one (also observed for PS series) is related to emission of water absorbed in the precursor’s pores (Fig. 1b—m/z lines 17 and 18). Higher decomposition loss occurs from 190 °C and is linked with carbonization process. It can be divided into two steps associated with splitting of –NHCHO groups from polymer [19]. The reduction of active material precursor (SnO2) starts above 450 °C, which is established by carbon dioxide evolution in the QMS curves (Fig. 1b). For PS series, formation of carbon begins from 250 °C and it is connected with decomposition of –CHO chains (Fig. 1d). Subsequently (from 725 °C) the SnO2 carboreduction process is initiated.

Fig. 1
figure 1

Thermogravimetric studies (EGA-TG/DTG) of pyrolysis process of MPNVF/SnO2 (a, b) and PS/SnO2 (c, d) composites precursors

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The real values of carbon content in the obtained materials evaluated from TPO method are collected in Table 1. As it can be observed, estimated amount of carbon is close to the real values determined from thermogravimetric analysis.

Table 1 Carbon content in C/Sn nanocomposites and Sn melting process properties
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The powder X-ray diffraction results of the C/Sn nanocomposites are shown in Fig. 2. The XRD patterns indicate formation of tin cubic phase that belongs to I4 1 /amd space group (ICDD database, PDF-4 file #00-004-0673) in all presented composites. For the PS series, small amount of nanometric tin oxides corresponding to P4 2 /mnm space group (ICDD database, PDF-4 file #00-041-1445) is also identified. Lack of significant reflexes associated with carbon material suggests that carbon buffer matrix is amorphous. Nonetheless, sample containing 66 % of carbon from the MPNVF series reveals small hump in the place related to graphite, which can indicate that the graphitization degree (described as a ratio of disordered sp 3 to graphene-like sp 2 carbon) in this material is higher than in other samples. This observation is consistent with preliminary studies connected with pure carbon obtained from MPNVF precursor [19]. The crystallite sizes calculated for tin phase are collected in Table 2.

Fig. 2
figure 2

X-ray powder diffraction (XRD) patterns for samples from the MPNVF (a) and PS (b) series

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Table 2 Crystallites size, specific surface area, pore volume and average pore size of the C/Sn nanocomposites
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The TG/DTG/DTA measurements performed in the air are presented in Fig. 3. Depending on the series, TPO process starts at different temperatures. For MPNVF series, oxidation process may be divided into two stages. The first stage (340–520 °C) is accompanied with a strong exothermic effect (Fig. 3c), and it is related to carbon oxidation. It can be noticed that only for 66 % C/Sn MPNVF sample this process includes two steps (Fig. 3a) which can indicate that in this material two types of carbon are present. It would be worthwhile to do further studies linked with detailed carbon description; however, that point is not the main goal of the presented paper. The second stage of TPO process for MPNVF series associated with mass increase (520–800 °C) should be ascribed to tin oxidation. For PS series, TPO process consists of three stages. First one starts at 233 °C which is a value strongly connected to melting point of tin (231.9 °C) [20]. During this stage, tin in liquid state comes out through leaks in the material to the surface of the composite and oxidizes to SnO2. Magnification illustrated in Fig. 4b clearly shows described process. This effect is not observed for the samples from the MPNVF series (Fig. 4a), which is the proof that the materials from PS series have to be leaking. The second stage of TPO for samples from PS series (470–570 °C) is associated with exothermic carbon oxidation (Fig. 3f) and then (570–750 °C) is related to tin oxidation. It should be also noticed that for the PS series, humps for the last step of the oxidation are smaller than for the MPNVF series due to earlier oxidation of tin on the composite’s surface (Fig. 3a, d).

Fig. 3
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Comparison of temperature programmed oxidation (TPO) process for materials from the MPNVF (ac) and PS (df) series

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Fig. 4
figure 4

Magnification of TG graphs from TPO process of samples from MPNVF (a) and PS (b) series

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Detailed melting process of tin in resulting C/Sn composites performed in argon flow is presented in Fig. 5. The onset temperatures of melting point are equal to literature value (Table 1). The melting heat increases with the higher content of tin in the composites, although for the MPNVF series the melting heat values are greater, which can also confirm that some of tin dioxides particles in composites precursors of PS series are not well encapsulated in carbon buffer matrix and have not been reduced during pyrolysis process. These results are also consistent with the XRD studies.

Fig. 5
figure 5

Differential scanning calorimetry (DSC) of the melting process of tin in resulting nanocomposites from MPNVF (a) and PS (b) series

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The difference in textural properties of both nanomaterials’ series is shown in Fig. 6. All of the N2-BET isotherms belong to the type IV isotherms (IUPAC classification). For both series the surface area and pore volume increase with the higher carbon content in the samples (Table 2), which is also observed in Fig. 6. Greater morphology parameters for PS series, especially linearly increasing specific surface area together with carbon content and large pore volume, reveal that for PS compounds the pores are open through the composite. That also implies that the carbon matrix in PS series is leakiness.

Fig. 6
figure 6

Low-temperature nitrogen (N2-BET) adsorption and desorption isotherms of nanopowders from MPNVF (a) and PS (b) series

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The comparison of electrochemical performance for cells assembled using materials from both series is presented in Fig. 7. The detailed data associated with specific charge capacity of the best electrochemical working cells from both series are collected in Table 3. In line with expectation, the best electrochemical performance demonstrates electrode containing 66 % C/Sn MPNVF anode material (Fig. 7a). The results suggest that the higher carbon loading in the C/Sn nanocomposites provides effective protection against the active material volume expansion which is reflected in higher capacity in charge–discharge tests. That observation also complies with our previous studies [16].

Fig. 7
figure 7

Charge–discharge capacity of anode materials from MPNVF (a) and PS (b) series

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Table 3 Comparison of specific charge capacities and efficiency for assembled cells
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Conclusions

The leak-testing studies of C/Sn nanocomposites were performed using for the first time thermal analysis methods (TG/DTG/DTA and DSC). Obtained thermogravimetric results highlight the important role of the origin of carbon buffer matrix. The TPO method showed that samples from PS series demonstrate high level of leaks in the examined materials. High values of specific surface area, as well as pore volume for PS series, reveal presence of the open pores through the composites. Those observations were confirmed by the low-temperature nitrogen adsorption (N2-BET).

The results linked with specific charge capacity of investigated cells indicate that carbon source has also a significant impact on the electrochemical performance of the assembled batteries, especially gravimetric capacity and cell efficiency. The 66 % C/Sn electrode material from the MPNVF series exhibits better cycling performance (657 mAh g−1 after 10 cycles) than the corresponding 65 % C/Sn material from the PS series (424 mAh g−1 after 10 cycles) which correlates with conducted thermal and morphology studies.