Y. LAN et al.: CHARACTERIZATION AND NITRIDATION BEHAVIORS OF SILICON SAWDUST ... 683–688 CHARACTERIZATION AND NITRIDATION BEHAVIORS OF SILICON SAWDUST GENERATED IN THE PHOTOVOLTAIC INDUSTRY KARAKTERIZACIJA IN OBNA[ANJA NITRIRANEGA SILICIJEVEGA PRAHU, NASTALEGA V FOTOVOLTAI^NI INDUSTRIJI Yu Lan 1 , Yi Huang 1 , Bing Li 1 , Xiaomin Li 1 , Xiuqin Wei 2 , Lang Zhou 1 , Chuanqiang Yin 1* 1 Institute of Photovoltaics, Nanchang University, 999 Xuefu Avenue, Honggutan New District, Nanchang City, Jiangxi Province, 330031, China 2 School of Materials Science and Engineering, Nanchang University, 999 Xuefu Avenue, Honggutan New District, Nanchang City, Jiangxi Province, 330031, China Prejem rokopisa – received: 2019-12-22; sprejem za objavo – accepted for publication: 2020-06-09 doi:10.17222/mit.2019.304 Characterization of the silicon-sawdust powders generated in the photovoltaic industry, and experiments of their nitridation were carried out. The results show that a layer of amorphous silicon is present on the particles of silicon sawdust. In addition, there is a lattice distortion in the crystal portion of the sawdust powders. An extra exothermic process accompanied by acceleration of nitridation occurs in the early stage of the nitridation of sawdust silicon, presumably because of the crystallization of the amor- phous phase of silicon sawdust. A successful preparation of >95 w/% -Si3N4 powders taking place at 1300 °C for 3 hours was carried out. Keywords: silicon sawdust, silicon nitride, nitridation, kinetics Avtorji v ~lanku opisujejo karakterizacijo silicijevega prahu, nastalega med rezanjem rezin z diamantno `ago, za fotovoltai~no industrijo in preizkuse nitriranja za njegovo ponovno uporabo. Rezultati analiz so pokazali, da je na povr{ini pra{nih delcev tanka plast amorfnega silicija. Poleg tega obstaja dolo~en dele` pra{nih delcev z deformacijo kristalne re{etke. Avtorji so ugotovili, da med nitriranjem Si prahu nastopi zato poseben eksotermni proces, ki pospe{i postopek nitriranja. Ta proces poteka v za~etni (zgodnji) fazi nitriranja zaradi kristalizacije amorfne faze, ki se nahaja na povr{ini Si pra{nih delcev. Avtorji so uspe{no reciklirali odpadni Si prah in pripravili -Si3N4 prahove s ~istostjo ve~ kot 95 mas.% z novim postopkom nitriranja s 3 urnim zadr`evanjem Si prahu na 1300 °C v ~istem du{iku. Klju~ne besede: silicijev prah, nastal med rezanjem rezin; fotovoltaika, silicijev nitrid, nitriranje, kinetika 1 INTRODUCTION The global photovoltaic (PV) industry developed rap- idly in the last decade, and more than 90 % of its opera- tions are based on silicon wafers. Up to now, all the sili- con wafers have been produced with a wire saw. As the width of kerfs is about the same as the thickness of wa- fers, about 50 % of the high-purity silicon becomes saw- dust. Their recovery and utilization are undoubtedly very important to reduce the cost of PV power and release the environmental load they create. The reuse of recovered sawdust as the feedstock for the multi-crystalline sili- con-ingot production used to attract a great deal of re- search effort. 1,2 However, none of it led to an industrial practice due to the difficulty in meeting the demand for the solar-grade purity and the fact that the price of proper silicon feedstock has decreased drastically in the recent years. Other simple uses of sawdust, such as using it as the raw material for refractory ceramics, deoxidizer in steel making or alloying material for Al-Si alloy making are regretfully of a much lower value than sawdust ought to have. Although it is difficult to reach a purity of 6–7 N, i.e., the standard for solar cells, sawdust can be easily cleaned to a purity of 4–5 N, 3 appropriate for higher- value utilization. In recent years, we have developed a patented route of producing high-purity -Si 3 N 4 powders using the nitridation of sawdust. Both and phases of Si 3 N 4 are formed during the nitridation of silicon, and -Si 3 N 4 is preferable for applications in ceramics. The present paper shares some fundamental findings we ob- tained during this development, mostly related to the special structural feature of sawdust as compared to the conventional ball-milled silicon powders. Up to now, no similar study has been seen in commonly available pub- lished literature. Materiali in tehnologije / Materials and technology 54 (2020) 5, 683–688 683 UDK 67.017:546.281:502.21:523.9 ISSN 1580-2949 Original scientific article/Izvirni znanstveni ~lanek MTAEC9, 54(5)683(2020) *Corresponding author's e-mail: cqyin@ncu.edu.cn (Chuanquiang Yin) 2 EXPERIMENTAL PART Silicon sawdust from a diamond-wire sawing work- shop for monocrystalline-silicon-wafer production was used. Floatation separation, hydrochloric acid based on pickling and water rinsing were conducted to purify the sawdust. For comparison, a reference silicon powder ball-milled from fragments of broken silicon wafers were prepared. Ball-milled silicon powders are common raw materials used for the industrial production of Si 3 N 4 powders through direct nitridation. The temperature profile of the nitridation process is illustrated in Figure 1. Different dwell temperatures were chosen for the experiment. Nitrogen of 99.999 % purity was used as the reaction gas with 10 vol.% H 2 /90 vol.% Ar of 99.999 % purity as the diluent gas in the ex- perimental system. An X-ray diffractometer, the Bruker D8 FOCUS model, was used to characterize the structure and phase constitution of the silicon powders and nitridation prod- ucts, using Cu-K 1 radiation with a step size of 0.02° and a scanning speed of 0.4 s/step. The quantitative-analysis method developed by Z. Jovanovic and S. Kimura 4 was adopted to calculate the phase constitutions on the basis of the XRD results. A scanning electron microscope, the JSM 6701F model, was used to examine the micro- morphology of the silicon powders. A laser particle-size analyzer, the BT-9300H model, was used to determine the particle-size distribution of the silicon powders. In- ductively coupled plasma atomic emission spectroscopy, the Optima 5300DV model, was used to analyze the me- tallic impurity of the purified silicon-sawdust powders. Combined differential scanning calorimetry (DSC) and thermal-gravity analysis (TGA) of the sawdust and the ball-milled reference silicon powders were conducted with a SDT-Q600 thermogravimetric analyzer. 3 RESULTS AND DISCUSSION 3.1 Characterization of the silicon sawdust Concentrations of four major residual metals from the purified sawdust powders are listed in Table 1.A s can be seen, the metallic impurity level corresponds well to the requirement related to commercial high-purity sili- con nitride products. Table 1: Concentrations of four major residual metals from the puri- fied silicon sawdust, in mass fractions (w/%) Fe Al Cu Ca 0.00053 0.00033 0.00033 0.00094 The obtained particle-size profile of the purified saw- dust is plotted in Figure 2. The purified-silicon-sawdust particle size ranges from 0.1 μm to 7 μm, with an aver- age particle size of 1.15 μm. The ball-milled silicon pow- der is typically used in the industrial production of Si 3 N 4 , and its average particle size is 4 μm. Figure 3 shows the XRD patterns of the silicon saw- dust powder and the reference silicon powder. Remark- able differences are revealed. Firstly, the diffraction peaks of the sawdust are greatly broadened, especially at the lower part of the peaks; Secondly, a broad peak ap- pears in the spectrum of the sawdust at 52° and it can- not be associated with crystalline silicon. As the particle sizes of the two types of silicon powders are in the order of microns, the first difference may not be attributed to the difference in the particle size. Besides, the shapes of the broadened peaks featured by a much greater broaden- ing of their lower parts cannot be explained with the Scherrer broadening from the size effect. 5 Previous studies of surface analyses of diamond- wire-sawn silicon wafers with Raman spectroscopy showed that an amorphous layer of nanometer thickness is present on the surfaces. 6,7 Molecular-dynamics simul- ations 8,9 showed that a crystalline silicon surface cut by a diamond tip, as well as most parts of the silicon debris pushed away by the diamond tip transformed into amor- phous-phase silicon. Therefore, we believe that a saw- Y. LAN et al.: CHARACTERIZATION AND NITRIDATION BEHAVIORS OF SILICON SAWDUST ... 684 Materiali in tehnologije / Materials and technology 54 (2020) 5, 683–688 Figure 2: Obtained particle-size profiles of the purified sawdust and ball-milled reference silicon powder Figure 1: Temperature profile of the nitridation process used for sili- con-sawdust powders dust particle actually consists of an amorphous surface layer and a crystalline silicon core, and it is the amor- phous part that contributes to the observed bottom wid- ening of the peaks and the extra hill in Figure 3a. Fig- ure 3 also gives an XRD spectrum (C) of the amorphous silicon deposited on a Be substrate. The hills centered at 29° and 52° match well with the observed spectrum of the sawdust. However, the significant widening of the higher parts of the peaks cannot be explained with the exiting of the amorphous phase in sawdust. We believe that underneath the amorphous layer, a severe crystal deformation must have happened, generating significant amounts of lattice defects and residual strains, which all contributed to the widening of the XRD peaks. Diamond-wire sawing of silicon, which generates sawdust, is basically a plastic ploughing process. 10,11 We believe this mechanism is responsible for the severe de- formation and the transition to the amorphous phase. During the ball milling of silicon, generating the reference silicon powders, simple brittle cracking of the silicon occurred, but it did not cause similar changes to the structure of silicon. The micrograph of the silicon-sawdust powder is shown in Figure 4. The particles are mostly flaky, which agrees with the mechanism of diamond cutting. 10 Com- pared with the usual granular shape, this kind of shape is believed to be of benefit to the reactivity. 3.2 Nitridation behavior of the silicon sawdust First, nitridation experiments with pure N 2 at a dwell temperature of 1380 °C indicated in Figure 1 were car- ried out. XRD patterns of the obtained products are given in Figure 5. As can be seen, the phase constitutions of the two products are greatly different. The product from the sawdust is mainly -Si 3 N 4 , with the rest being -Si 3 N 4 , whereas the product from the reference milled silicon powder consists of residual silicon and -Si 3 N 4 . Only a very small trace of -Si 3 N 4 is detected. While the faster nitridation of silicon sawdust is not surprising, the large difference in the phase preference is unexpected and needs further attention to the reaction kinetics to un- derstand the processes. In order to understand the kinetics behaviors, com- bined DSC and TGA analyses of the isothermal reaction processes were conducted. Figures 6a and 6b present isothermal DSC and TGA curves of the two powders at 1380 °C, and one more set of curves for the sawdust at 1300 °C in nitrogen. The samples were heated to the set temperature in Ar in less than an hour, then nitrogen was allowed to flow into the chamber and the counting of the reaction time started. The weight gain is a direct indica- tion of the extent of nitridation, which incorporates the weight of nitrogen into the solid sample. A remarkable exothermic peak is present at an early stage of the saw- Y. LAN et al.: CHARACTERIZATION AND NITRIDATION BEHAVIORS OF SILICON SAWDUST ... Materiali in tehnologije / Materials and technology 54 (2020) 5, 683–688 685 Figure 3: XRD patterns of the silicon sawdust: a), ball-milled crystal- line silicon powder b) and amorphous silicon c), replotted from refer- ence. 12 To make the graph clear, the spectrum for the sawdust was magnified eight times Figure 5: a) XRD patterns of the nitridation products obtained from silicon sawdust and b) ball-milled reference silicon powder. Refer to Figure 1 for the nitridation process, in which the dwell temperature is 1380 °C Figure 4: SEM micrograph of the purified silicon sawdust dust exposure to nitrogen, but no such peak is found for the milled reference silicon. Such a heat release may sig- nificantly raise the local temperature. Higher tempera- ture is known to favor the formation of -Si 3 N 4 , while lower temperature favors the formation of -Si 3 N 4 . 13 Once the -phase nucleates during the above-mentioned heat-release stage, its subsequent growth keeps the same phase, though the subsequent temperature may not keep the excessive level, favoring the formation of the -phase. Being associated with the exothermic heat, the acceleration of the nitridation of silicon sawdust is ob- served from Figure 6b. Nitridation of silicon is a strongly exothermic pro- cess. However, in a normal continuous nitridation pro- cess, no exothermic peak appears in the isothermal DSC curve. Only in the case of extra excessive heat that can- not be transferred away in time, such a peak would ap- pear and the local temperature would rise up, leading to a rise in the nitridation rate, as can be seen in Figure 6b. This is what happened to the reference powder and saw- dust. In the nitridation experiments, much more powder is packed, more heat is generated and the transfer of heat from the interior of a sample pack is also more difficult so that the above difference is more pronounced. The fact that no residual silicon is detected in the product from the sawdust, while residual silicon in the product from the reference milled powder is still a major phase after the equivalent thermal process, as can be seen from Figure 5, also supports the above suggestion. As to the reason(s) for the extra heat generation dur- ing the nitridation of silicon sawdust, further studies are required. Crystallization of a significant portion of the amorphous phase in the sawdust, as indicated by Fig- ure 3, which is generally known to release heat, is a pos- sible reason. In the DSC and TGA curves of the sawdust at a lower temperature (1300 °C), the extra exothermic peak and the corresponding acceleration of nitridation are found to be delayed by 20 min, with the DSC peak becoming smoother. This agrees with the above sugges- tion as due to a decrease in the temperature, the crystalli- zation is delayed. 14 The remarkably high reaction rate of the sawdust sili- con is doubtlessly a significant advantage. However, for most applications of Si 3 N 4 powders in the manufacturing of structural ceramics, the -phase is preferred for its transformation to the -phase during high-temperature sintering, enhancing the densifying process. 15-17 So, a method to enhance the formation of the -phase instead of -phase is required. Actually, at the industrial scale of the nitridation of ground silicon powders, a high propor- tion of the -phase is also a problem due to the facts that the nitridation of silicon is always strongly exothermic and the size of packing in the production is inevitably large. The control of the nitridation rate is crucial here. Current practices include dilution of the gas by adding an inert gas or dilution of the solid by mixing Si 3 N 4 pow- ders with the silicon powders. 18,19 Lowering the process temperature may also help, but it is unfortunately infeasi- ble for the production involving ground silicon as the process may become unacceptably lengthy, as we can see Y. LAN et al.: CHARACTERIZATION AND NITRIDATION BEHAVIORS OF SILICON SAWDUST ... 686 Materiali in tehnologije / Materials and technology 54 (2020) 5, 683–688 Figure 6: Isothermal behaviors of silicon sawdust and ball-milled ref- erence silicon powder exposed to nitrogen: a) DSC, b) TGA Figure 7: XRD patterns of the nitridation products obtained from sili- con sawdust at different positions of the sample stack in the crucible: a) the top layer, b) the inner part. Refer to Figure 1 for the nitridation process, in which the dwell temperature is 1300 °C from the fact that in the current experiment, most of sili- con remained unchanged after a three-hour exposure to 1380 °C. For the silicon sawdust with a remarkably high reac- tion rate, we chose to lower the process temperature to prevent an excessive temperature rise, which stimulates the formation of the -phase. A nitridation experiment with the dwell temperature lowered to 1300 °C was car- ried out. The XRD patterns of the resultant products for the top layer and inner part of the packed sample powder are presented in Figure 7. As we can see, the -Si 3 N 4 phase becomes overwhelmingly dominant, though a small amount of residual silicon is also present. Table 2 lists the phase constitutions obtained on the basis of the XRD patterns. The amounts of the residual silicon and -Si 3 N 4 phase in both the top layer and inner part of the sample stack from the crucible are within, or just slightly over, the acceptable limits for most silicon nitride ce- ramic products. It is quite encouraging that with a signif- icantly lower processing temperature, the time required is still much shorter than that of the nitridation of the ball-milled silicon used to reach the same low level of re- sidual silicon. Table 2: Phase constitutions of the nitridation products of the silicon sawdust at different positions of the sample stack in the crucible (w/%), as obtained from the XRD data in Figure 7 -Si 3 N 4 -Si 3 N 4 Si The top layer 97.9 1.1 1.0 The inner part 95.0 3.9 1.1 4 CONCLUSIONS Based on the present studies, we conclude that: A layer of amorphous silicon is present on the parti- cles of the silicon sawdust generated during the sili- con-wafer production with diamond wire sawing, result- ing in a significant amount of amorphous silicon phase in the sawdust. In addition, there is a lattice distortion in the crystal portion of the sawdust powder. Nitridation of purified silicon sawdust is generally much faster than for the conventional ball-milled silicon powder, even when the process temperature is signifi- cantly lower. An extra exothermic process accompanied by an ac- celeration of nitridation occurs in an early stage of the nitridation of the sawdust silicon, presumably because of the crystallization of the amorphous phase of the silicon sawdust. It enhances the -Si 3 N 4 phase formation at 1380 °C. A successful preparation of high-purity -Si 3 N 4 phase powders was achieved using the nitridation of silicon sawdust at a relatively low temperature, 1300 °C, in only 3 h. The amount of the -phase obtained was higher than 95 w/% and the amount of the residual silicon was re- duced to 1 w/%. Acknowledgement This work was financially supported by the Youth Long-Term Project of the Jiangxi Province to Introduce Leading Innovative Talents, China (Grant No. jxsq2018106023), the Fundamental Research Fund for the Nanchang University, China (Grant No. cx2016017) and the Innovation and Entrepreneurship Training Pro- gram for College Students of the Nanchang University, China (Grant No. 20190402181). 5 REFERENCES 1 D. Sarti, R. Einhaus, Silicon feedstock for the multi-crystalline pho- tovoltaic industry, Solar Energy Materials and Solar Cells, 72 (2002), 1–4, 27–40, doi:10.1016/s0927-0248(01)00147-7 2 D. G. Li, P. F. Xing, Y. X. Zhuang, F. Li, G. F. Tu, Recovery of high purity silicon from SoG crystalline silicon cutting slurry waste, Transactions of Nonferrous Metals Society of China, 24 (2014)4 , 1237–1241, doi:10.1016/S1003-6326(14)63184-8 3 K. Tomono, S. Miyamoto, T. Ogawa, H. Furuya, Y. 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