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Published: 11 November 2019
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International Journal of Coal Science & Technology Volume 6, 611-620, (2019)
1.
Chemistry and Chemical Engineering Research Center of Iran, Tehran, Iran
2.
Department of Research and Technology, Tehran Province Gas Company, Tehran, Iran
The aim of this project is studying the effect of thermal operation parameters on the graphitization of self-diffused ethane-based catalytic coke. The novelty of this study refers to self-diffused metals that had given unique properties to the catalytic coke and had improved the graphitization degree at low temperatures. The main feature of this research is presenting a remarkable energy saving approach that uses low-cost installations for production of graphitized carbon. The experiments were performed in two steps including preparation of self-diffused ethane-based catalytic coke and then low-temperature graphitization of coke samples below 1500 °C. Characteristic tests were performed by determination of electrical resistivity and XRD pattern of graphitized samples including graphitization degree, aromaticity, coke rank, number of carbon rings, graphene thickness and length. The results revealed that the blanket atmosphere, final temperature and exposure time had the greatest impact on the aforementioned criteria, while the role of thermal ramp and sulfur content of catalytic coke was negligible. The electrical resistivity tests on the graphitized sample showed how the electrical resistivity of graphitized samples is a function of graphitization degree.
Solid carbons, cokes and chars consist of randomly arranged crystalline-phases that are imperfect and distributed in the solid matrix (Wissler 2006). Synthetic cokes (Pourabdollah 2018a) exhibit the properties of metals including electrical and thermal conductivity and of non-metals including lubricity, high thermal resistance and inertness (Feng et al. 2003) and are used in cathodic wells and oil wells (Pourabdollah 2017a, 2018b), batteries (Pourabdollah 2017b) and furnaces.
Catalytic graphitization of coal and hydrocarbons by transition metals has been used for encapsulation, formation of fibers and carbon nanotubes (De Jong and Geus 2000; Bokhonov and Korchagin 2002; Helveg et al. 2004). When the solid carbon is produced from a gas phase, the catalytic graphitization can intensify the reaction by forming a thin film of amorphous carbon on the catalyst particles (Anton 2005, 2008). Using nickel (Anton 2009) and iron (Bokhonov and Korchagin 2002) catalyzers, the graphitization was conducted with encapsulation of metal particles by graphite layers.
Interaction of metallic catalyzers (such as La, Ce and Pr) with coal, coke and graphite materials is based upon the chemical addition of fine powders of metals followed by heating and proceeding the reaction (Wang et al. 2016). On the other hand, the diffusion of some elements in the graphite matrix has been investigated and it was revealed that boron (Hennig 1965), argon and helium (SHIGENO et al. 1988), uranium (Loch et al. 1956), cesium (Carter et al. 2015) and iron (Stoneham 1979) diffuse in the coke matrix at elevated temperature, leading to the catalysis of the graphitization reaction.
Feng et al. (2003) investigated the crystallite structure of several coke samples during CO2 and air gasification. The thermal annealing of several coke samples were applied and followed by studying the evolution of carbon structure in the coke matrix and the results revealed a linear correlation between the annealing temperature and the stack height (L002) of carbon crystallite (Gupta et al. 2005). The carbon structure in the coke matrix, which has a non-graphitic and turbostratic scaffold, can capture inorganic impurities such as metals. The dimensions of graphitic-crystallite in the coke matrix is characterized by the interlayer spacing (c/2 = half the hexagonal lattice c-axis), the thickness of hexagonal packing (Lc = crystallite dimension in the c-axis direction) (Feret 1998; Lu et al. 2001; Sonibare et al. 2010; Mollick et al. 2015), the spread of carbon basal plane (La = crystallite dimension in the a-axis direction) (Sonibare et al. 2010; Mollick et al. 2015), aromaticity (Sonibare et al. 2010; Odeh 2015), coke rank (Yoshizawa et al. 2001; Sonibare et al. 2010), graphitation degree (Mollick et al. 2015) and number of carbon rings (Belenkov 2001) and grapheme layers (Mollick et al. 2015), which are determined from X-ray diffraction (XRD) patterns. Not only the bond strengths are not fixed along the crystallographic directions, but also a variety of voids, defects and cross-links are present in the coke matrix. Therefore, various reaction rates in the coke matrix show an anisotropic character and have a directional nature (Li et al. 2014).
The first aim of this study is to produce a catalytic coke from ethane feed at temperature 850 °C range along with the self-diffusion of some transition metals (Fe, Ni and Cr) as catalyzers of the upcoming reaction. The second aim is to optimize the low-temperature (850–1470 °C) catalytic graphitization reaction based upon the aforementioned self-diffused catalyzers. The third aim is to characterize the self-diffused catalytic graphitization of coke by XRD algorithms. The micro-texture terminology and the classification of graphite samples vary in different countries; hence, a reference method was developed for characterization of graphite scaffolds and measurement of their electrical resistance.
The experiments have been conducted in two sections including preparation of the catalytic coke from ethane feed in a gas cracker furnace and graphitization of the catalytic coke in a calcination kiln.
A cylindrical self-diffused catalytic coke was prepared inside a tubular reactor located in the hot section of gas-cracker furnace. The reactor was heated by a gas fuel stream from bottom (1175 °C) to top (157 °C) sections of furnace. In order to improve the thermal stability of tubular reactor, their optimum chemical composition was Fe, Ni, Cr and Nb (37 : 35 : 25 : 3 wt%), respectively. At the initial stage of the cracking process, a sulfidation stage is performed in order to cover the inside surfaces of tubular reactor and decrease the adhesion tendency of the catalytic coke. Therefore, dimethyl disulfide (DMDS) was injected into the stream of dilution steam for sulfidation at 1 h and 101 kPa. During the sulfidation, DMDS concentration in dilution steam was set to be 100–1000 ppm. Just after sulfidation, the coils temperature was optimized to be 825–836 °C and the steam flow was co-injected.
Ethane feed along with dilution water steam and DMDS was injected into the tubular reactor leading to gradual formation of catalytic coke layer on the inside surface of the tubes. In the cracking temperature (800–820 °C), the transition metals are self-diffused into the produced coke. The behavior of catalytic coke shows that a filamentous morphology and Fe, Ni and Cr from the metal matrix of the reactor walls diffuse into the filaments coke matrix (Reyniers et al. 1994). For the consideration of energy saving, the cooling water was directed to a steam boiler as boiler feed water (BFW) for production of dilution steam. After increasing the coke thickness and reducing the interior diameter of tubular reactor, the furnace was switched to the decoking stage, at which the cylindrical catalytic coke was separated from the tubular reactor by steam and air injection at hot temperatures (810–850 °C). Figure 1 shows a schematic of ethane cracker furnaces, their flow diagrams and the tubular reactor direction.
Schematic representation of ethane cracker furnace for production of self-diffused catalytic coke
The cylindrical samples of catalytic coke were milled and sieved in the particle range of 0.1–1.0 mm. The calcination of coke breeze was performed in a reactor embedded in box furnace (REBF) under controlled atmosphere, temperature and time. The calcination of catalytic coke breeze were carried out in different conditions including N2, water steam, air and CO2 atmospheres, the temperatures of 850 °C, 1050 °C, 1350 °C and 1470 °C, temperature ramps of 5, 10, 15 and 20 °C/min, the range of sulfur content 0% – 1.0%, 1.0% – 2.0%, 2.0% – 3.0% and 3.0% – 4.0% wt. and the heating times of 1, 30, 60 and 120 min. The REBF was filled by ceramic balls (3 mm and 10 mm in diameter) as the supporting material and the catalytic coke breeze was filled and packed as presented in Fig. 2. The controlled atmosphere was flowed and exhausted from the sides of REBF. The ceramic balls not only improved the gas flow distribution but also prevented the choking tendency of fine particles in the exhaust line.
Graphical implementation of REBF filled by ceramic balls and catalytic coke
The calcination was designed by Taguchi algorithm and the above-mentioned parameters (five items), each of them at four different levels, were optimized. Table 1 shows the examined parameters and the relevant levels. The agglomeration runs were designed according to design of experiments (DoE) methodology, based upon 6 terms of aromaticity (f), coke rank (CR), La, Lc, graphitization degree (g) and the number of carbon rings per lamella (N), respectively.
Parameters | Symbols | L1 | L2 | L3 | L4 |
|---|---|---|---|---|---|
Atmosphere | P1 | N2 | Water steam | Air | CO2 |
Temperature (°C) | P2 | 850 | 1050 | 1350 | 1470 |
Temperature ramp (°C/min) | P3 | 5 | 10 | 15 | 20 |
Sulfur content (wt%) | P4 | 0–1.0 | 1.0–2.0 | 2.0–3.0 | 3.0–4.0 |
Heating time (min) | P5 | 1 | 30 | 60 | 120 |
The electrical resistivity was evaluated using a micro-ohmmeter and the four-point soil box adopted for this application. The electrical current was applied between the outer-pins while the voltage was monitored between the inner-pins. The electrical resistance was determined by the appropriate values of electrical current and the voltage-drop was measured between the inner-pins.
The investigated parameters on the graphite samples include f-value, CR, La, Lc, g and N, which were determined by pattern recognition of XRD signals (Fig. 3). The signals include γ (17°), 002 (26°), 100 (42°), 101 (43°), 004 (53°), 103 (59°) and 110 (78°) in the range of 2θ = 5° – 80°. By improving the graphitization degree, the shape and the situation of XRD signals are varied leading to orientation of the carbon scaffold. The step size and scanning rate of XRD tests were fixed to be 0.02 degrees 2-theta and 10°/min, respectively.
XRD pattern of un-graphitized coke
The strength of signals (I), the area behind them (A), the full width at half maximum (FWHM, B) and the angle of signal (φ) are the key elements to formulate the graphitization process of cracked cokes. The subscripts a and c are corresponded to (100) and (002) peaks, respectively. Table 2 shows the above-listed parameters for two distinct signals that have been obtained during the pre-designed experiments. Figure 4 shows the XRD patterns of all the samples.
Run | A002 (counts-2θ) | Aγ (counts-2θ) | I26 (counts) | I20 (counts) | Ba (rad) | Bc (rad) | φa (°) | φc (°) |
|---|---|---|---|---|---|---|---|---|
1 | 40100 | 479 | 8020 | 652 | 0.0065 | 0.0045 | 20.95 | 13.20 |
2 | 39800 | 502 | 7990 | 652 | 0.0065 | 0.0043 | 20.9 | 13.20 |
3 | 50150 | 489 | 10010 | 713 | 0.0063 | 0.0034 | 20.95 | 13.25 |
4 | 45000 | 491 | 9020 | 719 | 0.005 | 0.0041 | 20.9 | 13.24 |
5 | 4800 | 520 | 990 | 688 | 0.0174 | 0.0175 | 20.5 | 12.94 |
6 | 10100 | 492 | 2030 | 689 | 0.0162 | 0.0172 | 20.5 | 12.96 |
7 | 9980 | 490 | 2000 | 700 | 0.0154 | 0.0155 | 20.55 | 12.97 |
8 | 14400 | 492 | 2890 | 650 | 0.0128 | 0.0148 | 20.65 | 13.00 |
9 | 29950 | 478 | 5980 | 702 | 0.0109 | 0.0093 | 20.75 | 13.09 |
10 | 30100 | 520 | 6050 | 699 | 0.0108 | 0.0091 | 20.8 | 13.11 |
11 | 41000 | 552 | 8100 | 629 | 0.0085 | 0.0065 | 20.85 | 13.18 |
12 | 36000 | 551 | 7210 | 791 | 0.0092 | 0.0081 | 20.85 | 13.16 |
13 | 14400 | 539 | 2890 | 681 | 0.0133 | 0.0139 | 20.6 | 13.01 |
14 | 20500 | 589 | 4120 | 680 | 0.0119 | 0.0107 | 20.7 | 13.06 |
15 | 24400 | 522 | 4900 | 640 | 0.0101 | 0.0095 | 20.7 | 13.08 |
16 | 30300 | 520 | 6070 | 641 | 0.0101 | 0.0087 | 20.75 | 13.10 |
XRD patterns of all the samples
ASTM D5187 covers the determination of the mean crystallite thickness of coke samples by XRD patterns that are obtained by conventional X-ray scanning instruments. The XRD pattern was obtained in the range of 5°–85°2θ using Cu tube (λ = 1.54Ǻ) and R1-6 are determined by Eq. 1 to Eq. 7.
where in Eq. 1, Car and Cal show the number of aromatic and aliphatic carbons (Lu et al. 2001; Odeh 2015), respectively. Likewise, A002 and Aγ represent the integrated area under the corresponding peaks 002 (2θ = 26.7°) and γ (2θ = 17°–20°), respectively. On the other hand, in Eq. 2, I26 and I20 reveal the peaks intensity at positions 2θ = 20° and 2θ = 26°, respectively. In Eqs. 3 and 4, B and φ show the half width of peaks (2θ, radians) and the corresponding scattering angles (θ, degree), respectively. The subscript signs a and c are corresponded to (100) and (002) peaks, respectively. d002 in bragg’s equation (Eq. 5) exhibits the interlayer spacing, in which n is a positive integer and λ is the wavelength of the incident wave (Cu, 1.54Ǻ).
Therefore, all of 6 responses (R1 to R6) are controlled by eight readouts obtained from the XRD patterns of individual coke and graphite samples that were produced from run 1 to run 16. According to Eqs. 1–6, these readouts are including A002, Aγ, I26, I20, Ba, Bc, φa and φc. The next section reveals the results of XRD experiments representing the above-listed readouts.
In Table 3, the terms of R1-6 reveal the responses obtained by XRD patterns of graphitized coke samples, which has been used for the determination of coke crystallinity including f-value, CR, La, Lc, g and N.
Run | Parameters | Responses | |||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
P1 | P2 | P3 | P4 | P5 | R1 | R2 | R3 | R4 | R5 | R6 | |
1 | N2 | 850 | 5 | 0–1.0 | 1 | 0.99 | 12.3 | 467 | 313 | 0.79 | 94 |
2 | N2 | 1050 | 10 | 1.0–2.0 | 30 | 0.99 | 12.3 | 467 | 327 | 0.79 | 98 |
3 | N2 | 1350 | 15 | 2.0–3.0 | 60 | 0.99 | 14.0 | 482 | 414 | 0.94 | 124 |
4 | N2 | 1470 | 20 | 3.0–4.0 | 120 | 0.99 | 12.5 | 607 | 343 | 0.91 | 103 |
5 | Water steam | 850 | 10 | 2.0–3.0 | 120 | 0.90 | 1.4 | 174 | 80 | 0.02 | 24 |
6 | Water steam | 1050 | 5 | 3.0–4.0 | 60 | 0.95 | 2.9 | 187 | 82 | 0.08 | 25 |
7 | Water steam | 1350 | 20 | 0–1.0 | 30 | 0.95 | 2.9 | 197 | 91 | 0.11 | 27 |
8 | Water steam | 1470 | 15 | 1.0–2.0 | 1 | 0.97 | 4.4 | 237 | 95 | 0.20 | 29 |
9 | Air | 850 | 15 | 3.0–4.0 | 30 | 0.98 | 8.5 | 278 | 151 | 0.47 | 46 |
10 | Air | 1050 | 20 | 2.0–3.0 | 1 | 0.98 | 8.7 | 281 | 155 | 0.53 | 47 |
11 | Air | 1350 | 5 | 1.0–2.0 | 120 | 0.99 | 12.9 | 357 | 217 | 0.73 | 65 |
12 | Air | 1470 | 10 | 0–1.0 | 60 | 0.98 | 9.1 | 330 | 174 | 0.67 | 52 |
13 | CO2 | 850 | 20 | 1.0–2.0 | 60 | 0.96 | 4.2 | 228 | 101 | 0.23 | 31 |
14 | CO2 | 1050 | 15 | 0–1.0 | 120 | 0.97 | 6.1 | 255 | 131 | 0.38 | 40 |
15 | CO2 | 1350 | 10 | 3.0–4.0 | 1 | 0.98 | 7.7 | 300 | 148 | 0.44 | 45 |
16 | CO2 | 1470 | 5 | 2.0–3.0 | 30 | 0.98 | 9.5 | 300 | 162 | 0.50 | 49 |
The results of Taguchi algorithm revealed that among five parameters, the atmosphere composition strongly affected the graphitization efficiency. Increasing the maximum temperature from 850 to 1470 °C as well as the exposure time of thermal operation from 0 to 120 h led to the improvement of the graphitization of catalytic coke. Likewise, the temperature ramp of 15 °C/min and sulfur content range of 1%–2% wt. revealed the other optimum conditions. Figure 5 shows the graphical implementation of Taguchi response by five parameters and four levels.
Schematic illustration of Taguchi response for graphite-optimization of catalytic coke
As presented in Fig. 5, the gasification (water–gas shift) reaction by water steam and CO2 (Chianese et al. 2015) has decreased the graphitization efficiency of ethane-based catalytic coke. The experimental results revealed that water steam decreases the graphitization efficiency of ethane-based catalytic coke. Water steam loses the coke structure, leading to the increasing of the structural damage of polycyclic planes of catalytic coke. This damage is the main cause of micro-fractures in the body of deposited coke used in decoking operation of gas crackers of refineries. At high temperatures, the thermal decomposition of water steam on the carbon surfaces helped form active hydrogen atoms that are responsible for ring opening of polycyclic aromatic scaffolds of coke matrix and the decreasing of the graphite properties. On the other hand, CO2 atmosphere limits the graphitization phenomena of catalytic coke because of the enhancement of the gasification process.
It was demonstrated that aforementioned Cr (Chianese et al. 2015), Ni (Zhao et al. 2014; Guo et al. 2015) and Fe (Chianese et al. 2015) dopants preset in the matrix of catalytic coke catalyze the gasification reactions under water steam and CO2 atmospheres. The unique thermophysical properties of H2O and CO2 are responsible for distinct reactions of catalytic coke under gasification process (Hwang et al. 2011; Zhu and Wachs 2015) as Eqs. 8–10 explain:
In air atmosphere, the burning process of catalytic coke was carried out, activating rings opening of polycyclic aromatics and losing the graphite planes at annealing conditions, while under nitrogen atmosphere none of the gasification and burning reactions was carried out to improve the graphitization process at the temperatures of interest.
While some carbon-substrates attain ordered orientation at temperatures below 2000 °C, the other carbonaceous materials do not exhibit such ordered scaffold even above 3000 °C. Therefore, the graphitization reactions also depend on the scaffold of the materials being graphitized (Gupta et al. 2017). On the other hand, carbon graphitization at relatively low temperatures (below 1500 °C) has been assessed by low dosage injection of some transition metals (such as Fe, Ni and Mn) (Sevilla and Fuertes 2006; Barbera et al. 2014) as the scope of the present study.
The effect of graphitization temperature was assessed in the range of 850–1470 °C and the results showed that the graphitization was enhanced at high temperatures up to 1470 °C, at which the structural modifications of polycyclic scaffolds were occurred and more desulfidation was performed. High temperature desulfurization is discussed in the next section. Figure 6 shows the effect of maximum temperature on the graphitization degree of catalytic coke, schematically.
Graphical implementation of graphitization degree versus heating temperature
The coke samples were graphitized at 850 °C showing a broad signal at 26°2θ (002) along with a shoulder at 42°2θ (100). By increasing the temperature of graphitization to 1050 °C the broad signal was split into three segments having signal centers at 23°2θ, 26°2θ and at 31°2θ. The middle signal was sharp (FWHM = 3.43°) at 2θ value closer to the anticipated 002 signal of graphite. Upon further increase in temperature to 1350 °C, this signal was further narrowed (FWHM = 2.43°). Reduction of signal width was continued when the temperature was increased to 1470 °C. The middle signal at 26°2θ was further narrowed (FWHM = 2.03°). Decreasing of signal width along with increasing the graphitization temperature reveals the increasing of sp2-bonded content in the coke matrices.
When the metal-impregnated catalytic coke is heat-treated under nitrogen atmosphere, the metallic species are reduced from the metal oxide to the elemental metal (e.g. Fe and Ni). At temperatures higher than 800 °C, the self-diffused metallic particle contained within the coke media acted as catalyst for the conversion of amorphous-carbon to more ordered graphitic-carbon. The type of doped metal has a great role in the graphitization of coke samples. In this regard, Sevilla and Fuertes (Sevilla and Fuertes 2006) studied the effect of three metals on the graphitization degree and they proposed the following order: Ni > Mn > Fe.
The samples of petroleum coke were normally calcined up to 1400 °C and desulfurization was carried out to a significant degree within this temperature range. However, the desulfurization efficiency was not only dependent on the applied temperature, but also was affected by other parameters including the heating ramp, residence time, gas blanket atmosphere and the concentration of catalytic metals. Thermal desulfurization of catalytic coke was conducted along with the graphitization reaction, simultaneously and it is divided into four phases as the following (Al-Haj-Ibrahim and Morsi 1992).
Initial phase of desulfurization (850 °C)
The sulfur bounds on the surfaces or in the matrix pores are broken and simultaneously the side chains of aromatic molecules are cracked. The maximum amounts of sulfur removed in this phase are reported to be less than 25% since no reaction takes place between sulfur and metals and no variation is observed in desulfurization degree of catalytic cokes with self-diffused metals.
Second phase of desulfurization (1050 °C)
In this phase, little or no desulfurization is performed as it is significantly depressed by the self-diffused metals (e.g. Ni) that react with dissociated-sulfurs to form refractory-sulfur. Ash and self-diffused metals seem to have no effect on desulfurization up to this temperature, while at temperatures greater than or equal to 1050 °C desulfurization is further inhibited by forming a thermally stable metal-sulfide.
Third phase of desulfurization (1350 °C)
Upon further increase in temperature of catalytic coke to 1350 °C, the available energy is enough high for the decomposition of sulfur-hydrocarbon compounds such as thiophenes. In this phase it is not possible to eliminate total sulfur from the coke matrix since the desulfurization degree is significantly related to total sulfur content of the coke.
Third phase of desulfurization (1470 °C)
Further increase in temperature cannot lead to more desulfurization, since it depends mainly on the nature of coke. In this phase, the apparent density of catalytic coke was increased from 1.3(± 0.1) to 1.8(± 0.2). In this temperature range, the density change depends on the initial sulfur-content. In the presence of high sulfur-content cokes, the coke density was decreased; and with coke samples of low sulfur-content, the density was increased. The decrease of apparent density at 1470 °C, which is called the puffing phenomenon, is the result of porosity development when the sulfur-species get out from the coke media.
Abdul Abas et al. (Abas et al. 2006) studied the graphitization of blast furnace coke and they reported that the graphitization degree is independent from time. However the results of the present study revealed that the graphitization criteria of catalytic coke are declined by increasing the exposure time. This may be due to the high surface energy of the coke, which intensifies the time-dependent puffing phenomena at elevated temperatures. The porosity development of the aged samples of heat-treated coke leads to decreasing the graphitization criteria.
The success of catalytic graphitization can be assessed by a notable improvement in the electrical resistivity (ρ) (Sevilla and Fuertes 2006). The electrical resistivity of graphitized coke samples depends mainly on the atmosphere, the exposure time and the temperature employed. Figure 7 shows the linear dependency of ρ to g, representing a threshold point at g = 10% and ρ = 65Ω.cm.
Linear dependency of g vs. ρ for the graphitized samples of ethane-based coke
Coke formation in tubular reactors is a steady state process, which takes place in long periods of time, in the range of several days. At enough high temperatures, iron and nickel elements diffuse into the coke matrix along with chromium migration leading to formation of a ferromagnetic coke. Distribution of the above-mentioned elements in the coke matrix was studied by EDX–mapping (Tsuneta et al. 2002; Allen et al. 2012) and the results revealed that the concentration of the diffused elements is reduced from the exterior surface to the inner surface of coke layer. On the other hand, the concentration of sulfur-containing compounds was studied along the thickness of the coke layer by EDX–mapping and the results revealed that sulfur concentration is increased from the outer to the inner surface. Figure 8 shows a schematic representation of metal and sulfur distribution in the coke matrix.
EDX-mapping of the deposited coke on the inner surfaces of tubular reactor
Self-diffusion of some structural metals into the coke matrix varies their reactivity and their responses in thermal operations.
The blanket atmosphere, final temperature and exposure time showed a remarkable effect on the aforementioned criteria, while the role of thermal ramp and sulfur content of catalytic coke was negligible.
The gasification reaction by water steam and CO2 leads to decrease the graphitization efficiency of ethane-based catalytic coke. On the other hand, in air atmosphere, the burning process of catalytic coke causes the rings opening of polycyclic aromatics and losing the graphite planes at annealing conditions. Under nitrogen atmosphere, none of the gasification and burning reactions was carried out leading to improve the graphitization process at the temperatures of interest.
At elevated temperatures, the high surface energy of coke samples intensifies the time-dependent puffing phenomena leading to porosity development of the aged samples and decreasing the graphitization criteria.
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03 June 2019
29 August 2019
14 October 2019
December 2019
https://doi.org/10.1007/s40789-019-00279-y
Springer
