Fine Activated Carbon from Rubber Fruit Shell Prepared by Using ZnCl 2 and KOH Activation

: Fine activated carbon (FAC) is prepared from rubber fruit shells (RFS) using two chemical activating agents (ZnCl 2 and KOH) and three impregnation ratios (1:3, 1:4, and 1:5). The Brunauer– Emmett–Teller (BET) results show that for a constant impregnation ratio, the ZnCl 2 activating agent yields a higher speciﬁc surface area than the KOH agent. In particular, for the maximum impregnation ratio of 1:5, the FAC prepared using ZnCl 2 has a BET surface area of 456 m 2 /g, a nitrogen absorption capacity of 150.38 cm 3 /g, and an average pore size of 3.44 nm. Moreover, the FAC structure consists of 70.1% mesopores and has a carbon content of 80.05 at.%. Overall, the results conﬁrm that RFS, activated using an appropriate quantity of ZnCl 2 , provides a cheap, abundant, and highly promising precursor material for the preparation of activated carbon with high carbon content and good adsorption properties activation performance. This may be because the RFS is lignocellulosic materials [50] with a greater content of oxygen and the ZnCl 2 is an acidic reagent capable of interacting with functional oxygen groups in RFS charcoal, thus catalyzing dehydration reactions, resulting in charring and creation of the pore structure [43]. ratio. For the highest impregnation ratio of 1:5, the ZnCl 2 -activated RFSFAC has a BET surface area of 456 m 2 /g, an average pore size of 3.44 nm, a nitrogen absorption capacity of 150 cm 3 /g, a 70% mesoporous structure, and a carbon content of 80.05 at.%. Overall, the results indicate that RFS has signiﬁcant potential as a low-cost, abundant, and effective precursor for the preparation of FAC with high carbon content.

According to the Republic of Indonesia Ministry of Agriculture [23], Indonesia has an estimated 3.671.387 ha of rubber plantations. On average, a rubber plantation produces around 1000 kg/ha/yr of rubber seed or fruit [24]; equivalent to roughly 3.6 million tons of rubber fruit shells (RFSs) per year. While rubber seeds can be used to produce rubber seed oil [25], the majority of the shells are left as plantation waste, and hence pose a major environmental concern. Accordingly, in this study, we explore the feasibility of using RFS as a precursor material for the preparation of fine activated carbon (FAC).
The preparation of activated carbon generally involves two steps, namely pyrolysis (or precursor carbonization) and activation [25]. The activation step may be performed using either physical or chemical methods [25]. Chemical methods use many different activators, including alkali (e.g., KOH and NaOH), acidic (e.g., H 3 PO 4 and H 2 SO 4 ), and chemical compound salt (e.g., AlCl 3 and ZnCl 2 ) [26]. Among these agents, KOH and ZnCl 2 are two of the most commonly used agents, since their chemical activation can produce the highest surface area and yield values [26,27]. Generally speaking, the activation performance of chemical agents is strongly dependent on the temperature at which the activation process is performed. For example, the optimal temperatures for KOH and ZnCl 2 are around 800 • C [28][29][30][31] and 500 • C [32][33][34], respectively. However, while KOH and ZnCl 2 are commonly used in the preparation of activated carbon nowadays, the literature contains little information on their use in preparing FAC with RFS as a precursor.
Accordingly, in the present study, we prepare activated carbon using RFS as raw material and KOH and ZnCl 2 as activating agents. In performing the activation process, the temperature is set at 800 • C for the KOH agent and 500 • C for ZnCl 2 . For both activating agents, the activation process is performed using three different impregnation ratios, namely 1:3, 1:4, and 1:5. Following the activation experiments, the properties of the various RFSFACs (i.e., the element composition, specific surface area, pore size distribution, and structure) are systematically explored to determine the optimal activation agent and processing conditions for large-scale preparation of FAC utilizing RFS as a low-cost, green carbon source.

Material Preparation
The RFSs were obtained from Bangka Island (Indonesia). First, 150 g of RFS was immersed in 10% H 2 SO 4 solution for 4 h, washed in distilled water to remove soil impurities, and then dried in an oven at 60 • C for 24 h. The dried precursor was placed in a heating box and carbonized at 450 • C for 1 h in nitrogen (flow rate 20 mL/min). Finally, the carbonized RFSs were crushed and sieved using a 200 mesh/74 µm sieve size.
Three grams of RFS powder were mixed with an activating agent (ZnCl 2 or KOH solution) with impregnation ratios of 1:3, 1:4, and 1:5, respectively (see Table 1). The ZnCl 2 solution had a composition of 10% ZnCl 2 (w/v) aqueous solution [35], while the KOH solution had a composition of 50% (w/v) aqueous solution [36]. Both slurries were mixed at 1000 rpm for 1.5 h to obtain a homogeneous slurry, and then were dried in an oven at 110 • C overnight. In the ZnCl 2 activation process, the dried slurry was simply heated at 500 • C for 1 h [32][33][34]37]. By contrast, in the KOH activation process, first, the slurry was heated at 450 • C for 0.5 h, and then at 800 • C for a further 2 h [28][29][30][31]38]. For both activation processes, the obtained RFSFAC was washed with 1M HCl and distilled water repeatedly in order to remove any activation agent residuals, and then was dried in an oven at 110 • C for 24 h.

Characterization
The proximate analysis was comprised of the mass percentages of moisture, volatile matter, fixed carbon, and ash of the various RFSFACs that were performed using thermogravimetric analysis (TGA) [39]. For each RFSFAC, 10 mg of sample was heated from room temperature to 120 • C at a rate of 50 • C/min and held at 120 • C for 3 min. Then, the sample was heated to 950 • C at a rate of 100 • C/min before being cooled to 450 • C at a rate of −100 • C/min. To prevent oxidation, the heating and cooling processes were performed under nitrogen gas. However, when the temperature reached 450 • C, the protective gas was changed to air and the sample was reheated to 800 • C at a rate of 100 • C/min. Then, it was held at this temperature for 3 min to achieve isothermal conditions, thereby, marking the end of the process. The thermal decomposition behavior of the RFSFACs was likewise investigated by TGA. Briefly, 10 mg of the sample was heated from room temperature to Appl. Sci. 2021, 11, 3994 3 of 12 950 • C at a rate of 10 • C/min under a nitrogen gas flow rate of 20 mL/min. Then, the resulting weight loss curves were replotted using Origin ® 8 software (OriginLab Corporation, Northampton, England).
The pore volumes and specific surface areas of the RFSFAC products were determined using an accelerated surface area and porosimetry system (ASAP 2020) using 0.2~0.3 g of sample, an automatic degas process, nitrogen working gas, a −196 • C analysis bath temperature, a 10 s equilibration interval, and a 22 • C ambient temperature. The specific surface areas of the products were obtained using the Brunauer-Emmett-Teller (BET) method. Finally, the pore volume was calculated using the Barrett-Joyner-Halenda (BJH) algorithm.
The surface structures and element compositions of the various RFSFAC products were additionally examined using X-ray diffraction and a field emission scanning electron microscope (JEOL JSM-6701F, JEOL Ltd., Tokyo, Japan) integrated with an energy dispersive X-ray spectrometry system (INCA, Vs. 4.14, Oxford Instruments KK, Tokyo, Japan). Table 2 presents the proximate analysis results for the various RFSFAC products. As shown, the moisture content of the KOH-activated products increases from 16.76 to 23.51 wt.% as the impregnation ratio increases from 1:3 to 1:5. Similarly, the moisture content of the ZnCl 2 -activated products increases from 13.31 to 14.98 wt.%. Meanwhile, the fixed carbon content increases from 16.26 to 23.84 wt.% for the KOH products and 23.26 to 38.09 wt.% for the ZnCl 2 products. The greater moisture content of the RFSFAC products under a greater impregnation ratio implies that a stronger activator concentration is beneficial for increasing the surface area of the activated carbon, and hence for increasing the hygroscopic properties of the product [40]. Meanwhile, the higher fixed carbon content of the activated RFSFACs with a greater impregnation ratio reflects a corresponding reduction in the volatile and ash content of the products. In particular, the volatile content of the KOH-activated products reduces from 56.38 to 42.24 wt.% as the impregnation ratio increases from 1:3 to 1:5, while that of the ZnCl 2 -activated products reduces from 48.24 to 33.44 wt.%. The reduction in the volatile content arises since the activators degrade the surface structure of the activated carbon, and thus facilitate the easier removal of the volatile substances [41]. There is also a slight reduction in the ash level with an increasing activator concentration, i.e., from 10.59 to 10.41 wt.% for the KOH-activated products and 15.19 to 13.50 wt.% for the ZnCl 2 products. It is speculated that the reduction in the ash content is the result of a reaction between the activator and the minerals contained in the RFS raw material. It is noted that this inference is consistent with the findings of a previous study [41] which showed that the ash content produced during pyrolysis depends on both the amount and the composition of the mineral salts in the raw material.

Characterization of RFSFACs
Referring to the EDS analysis results presented in Table 2, it can be observed that the KOH-derived RFSFAC has a carbon content from 72.29 to 78.40 at.%. By contrast, the ZnCl 2 -derived FAC has a higher carbon content from 65.94 to 81.83 at.%. In other words, while both RFSFACs have a high carbon content, ZnCl 2 yields an improved activation effect. The EDS analysis results additionally show that the RFSFACs activated using KOH contain relatively large amounts of potassium, while those activated using ZnCl 2 have relatively large contents of chlorine and zinc. Figure 1 shows the thermal decomposition behaviors of the carbonized RFSFC charcoal and RFSFAC products, respectively. For the RFSFC product, the mass remains approximately constant until 400 • C, and then rapidly decreases, almost to zero at a temperature of 650 • C. The rapid weight loss at temperatures from 400 to 650 • C is associated mainly with the formation of ash as a result of devolatilization. Comparing the weight loss behaviors of the activated RFSFAC products, it can be obsserved that the products activated using KOH (i.e., RFSFAC1~3) decompose more rapidly than those activated using ZnCl 2 (RFSFAC4~6). For the RFSFC activated with KOH, the mass loss can be explained as follows: A significant mass loss occurs at around 150 • C as a result of dehydration and moisture evaporation [42].
Then, the mass loss is around 70% of the total weight percentage at a temperature of around 450 • C. The weight loss is primarily attributed to the decomposition of activating agencies. J. Zhang et al. [42] explained that when the temperature is around 200 • C, KHCO 3 is rapidly decomposed to H 2 O and CO 2 , leading to increased weight loss. At higher temperatures (e.g., from 700 to 900 • C), the mass continues to reduce due to the release of carbon oxide and potassium sublimation [43]. The following equation may describe the reaction on a carbon surface (C f ) using KOH activation [44,45]: (1) CO + H 2 O → H 2 + CO 2 (water-gas shift reaction)  [44] and the ac out at 800 °C, there is a significant loss of potassium metal XRD patterns, presented in Figure 2a, show that the activ pared using KOH have an amorphous carbon structure. The around 26.69° and 43.24° indicates that the carbon layer plan  During the activation process, K 2 CO 3 was formed, and the carbon was simultaneously reduced to K, K 2 O, and CO 2 , and a porous carbon surface was also developed. The metal of K was created at a temperature above 700 • C during activation of the K 2 O. The potential reaction could be as follows [45,46]: Because the boiling point of K is 780 • C [44] and the activation process was carried out at 800 • C, there is a significant loss of potassium metal in the activated carbon. The XRD patterns, presented in Figure 2a, show that the activated RFSFAC products prepared using KOH have an amorphous carbon structure. The presence of broad peaks at around 26.69 • and 43.24 • indicates that the carbon layer planes are aligned [47].
Because the boiling point of K is 780 °C [44] and the activation process was carried out at 800 °C, there is a significant loss of potassium metal in the activated carbon. The XRD patterns, presented in Figure 2a, show that the activated RFSFAC products prepared using KOH have an amorphous carbon structure. The presence of broad peaks at around 26.69° and 43.24° indicates that the carbon layer planes are aligned [47].  Referring to the TGA results in Figure 1, it can be observed that the ZnCl2-activated samples (RFSFAC4-6) experience a weight loss of around 80% by the end of the heating process. The significant reduction in mass that occurs over the temperature range from 150 to 450 °C can be attributed to the release of moisture from the solid-phase ZnCl2. The more gradual reduction in mass from 450 to 650 °C is, then, the result most likely of volatile evolution, while that at temperatures higher than 700 °C reflects the total evaporation of the liquid phase from the ZnCl2. Previous studies have reported that ZnO/carbon compounds are formed at 550 °C and reduce to metallic zinc at temperatures higher than 800 °C [21]. These findings are supported by the XRD patterns shown in Figure 2b for the present RFSFACs activated using ZnCl2. In particular, the sharp diffraction peaks at 31.74°, 34.38°, 36.22°, and 47.48° correspond to ZnO (PDF card 76-704), while those at 25.46°, 29.35°, and 38.29°, respectively, correspond to ZnCl2 (PDF card 74-517). Finally, the peaks at 26°, 62°, and 43.93° correspond to C (PDF card 26-1077) and indicate the existence of graphite in the activated RFSFAC products [48].
As shown in Figure 3a, the BET surface areas of RFSFACs 1~3 (prepared with KOH) are approximately 42, 141, and 160 m 2 /g, respectively. Similarly, the BET surface areas of RFSFACs 4~6 (prepared with ZnCl2) are 256, 400, and 456 m 2 /g, respectively (see also Table 3). For both sets of RFSFACs, the surface area increases with an increasing activator Referring to the TGA results in Figure 1, it can be observed that the ZnCl 2 -activated samples (RFSFAC4-6) experience a weight loss of around 80% by the end of the heating process. The significant reduction in mass that occurs over the temperature range from 150 to 450 • C can be attributed to the release of moisture from the solid-phase ZnCl 2 . The more gradual reduction in mass from 450 to 650 • C is, then, the result most likely of volatile evolution, while that at temperatures higher than 700 • C reflects the total evaporation of the liquid phase from the ZnCl 2. Previous studies have reported that ZnO/carbon compounds are formed at 550 • C and reduce to metallic zinc at temperatures higher than 800 • C [21]. These findings are supported by the XRD patterns shown in Figure 2b for the present RFSFACs activated using ZnCl 2 . In particular, the sharp diffraction peaks at 31  ) and indicate the existence of graphite in the activated RFSFAC products [48].
As shown in Figure 3a, the BET surface areas of RFSFACs 1~3 (prepared with KOH) are approximately 42, 141, and 160 m 2 /g, respectively. Similarly, the BET surface areas of RFSFACs 4~6 (prepared with ZnCl 2 ) are 256, 400, and 456 m 2 /g, respectively (see also Table 3). For both sets of RFSFACs, the surface area increases with an increasing activator concentration due to the enhanced effect of the activation substance seeping into the RFS charcoal and opening the surface [49]. It can be observed that for a given impregnation ratio, the ZnCl 2 activation agent results in a higher specific surface area than that obtained using KOH. In other words, of the two activating agents, ZnCl 2 provides a more effective activation performance. This may be because the RFS is lignocellulosic materials [50] with a greater content of oxygen and the ZnCl 2 is an acidic reagent capable of interacting with functional oxygen groups in RFS charcoal, thus catalyzing dehydration reactions, resulting in charring and creation of the pore structure [43]. tween 2 and 50 nm) in the KOH products gradually decreases with an increasing impregnation ratio, while the proportion of micropores (diameter < 2 nm) gradually increases. By contrast, for the ZnCl2 products, the proportion of mesopores increases, while the proportion of micropores decreases, as the impregnation ratio increases. It should be noted that these findings for the ZnCl2 products are consistent with those reported in [30] for the production of activated carbon from cocoa pod husks. In general, all of the present RFSFACs have around 60-80% micropores, 18-36% mesopores, and fewer than 4% macropores. However, of all the RFSFACs, RFSFAC6 has the highest pore area (40.61 m 2 /g) and percentage of mesopores (70.1%).    Referring to Figure 4a, the total pore area of the KOH-activated RFSFAC products increases from 11.88 to 26.17 m 2 /g as the impregnation ratio increases from 1:3 to 1:5 (see also Table 3). Similarly, for the ZnCl 2 -activated products, the total pore area increases from 20.47 m 2 /g to 40.61 m 2 /g. Furthermore, the proportion of mesopores (diameter between 2 and 50 nm) in the KOH products gradually decreases with an increasing impregnation ratio, while the proportion of micropores (diameter < 2 nm) gradually increases. By contrast, for the ZnCl 2 products, the proportion of mesopores increases, while the proportion of micropores decreases, as the impregnation ratio increases. It should be noted that these findings for the ZnCl 2 products are consistent with those reported in [30] for the production of activated carbon from cocoa pod husks. In general, all of the present RFSFACs have around 60-80% micropores, 18-36% mesopores, and fewer than 4% macropores. However, of all the RFSFACs, RFSFAC6 has the highest pore area (40.61 m 2 /g) and percentage of mesopores (70.1%).   Figure 5 presents the nitrogen adsorption isotherms of the various RFSFAC products. For all of the products, the nitrogen adsorption capacity increases rapidly in the low relative pressure regime (0 < P/P 0 < 0.2), but then increases more slowly with an increasing relative pressure before reaching an approximately constant value at a relative pressure of around P/P 0 = 0.98. The isotherms are consistent with those reported in [48,[51][52][53] and can be classified as type I isotherms based on the IUPAC classification. For both activation agents, the nitrogen adsorption quantity increases with an increasing impregnation ratio due to a widening of the microporosity. Since all of the RFSFACs have a similar isotherm type, it can be inferred that they all contain micropores. However, for a given relative pressure and impregnation ratio, the ZnCl 2 -activated products yield higher nitrogen adsorption than the KOH-activated samples. This may be due to the pore area and mesoporous structures that were created by ZnCl 2 which were higher than KOH. Thus, among all of the present RFSFAC products, the product prepared using the ZnCl 2 activating agent with an impregnation ratio of 1:5 yields the highest nitrogen adsorption quantity of 150.38 cm 3 /g.

Sample
BET (m 2 /g) Adsorption Quantity (cm 3 /g)  Figure 5 presents the nitrogen adsorption isotherms of the various ucts. For all of the products, the nitrogen adsorption capacity increases low relative pressure regime (0 < P/P0 < 0.2), but then increases more slow creasing relative pressure before reaching an approximately constant valu pressure of around P/P0 = 0.98. The isotherms are consistent with tho [48,[51][52][53] and can be classified as type I isotherms based on the IUPAC For both activation agents, the nitrogen adsorption quantity increases with impregnation ratio due to a widening of the microporosity. Since all of have a similar isotherm type, it can be inferred that they all contain micro er, for a given relative pressure and impregnation ratio, the ZnCl2-activ yield higher nitrogen adsorption than the KOH-activated samples. This the pore area and mesoporous structures that were created by ZnCl2 whic than KOH. Thus, among all of the present RFSFAC products, the produc ing the ZnCl2 activating agent with an impregnation ratio of 1:5 yields the gen adsorption quantity of 150.38 cm 3 /g. Figure 6 presents SEM micrographs of the various RFSFACs. L macropores are evident in all of the samples. However, no mesoporous can be seen due to the relatively low magnification level of the images (5 the images show that for both activating agents, the percentage of macro approximately unchanged as the impregnation ratio increases (see also Table 3).   due to the relatively low magnification level of the images (5000×). Overall, the images show that for both activating agents, the percentage of macropores remains approximately unchanged as the impregnation ratio increases (see also Figure 4b and Table 3).  Table 4 gives an overview of activated carbon characteristic results in this study, and some of the results of previous studies.

Discussion
The characteristics of activated carbon are highly dependent on the precursors used, the impregnation ratio, the carbonization time, and the carbonization temperature [59]. In other words, the use of different raw materials and activation treatments can result in activated carbons with very different properties. The RFSFAC6, with a ZnCl2 impregnation ratio of 1:5, surpasses all other samples (seen in Table 3). Using ZnCl2 as an activating agent, RFSAC formed a relatively stable carbon structure below 400 °C, and then began to deteriorate the carbon matrix, resulting in porosity between 400 and 500 °C. At higher temperatures, ZnCl2 has been vaporized and decomposed into zinc and chlorine, which could cause more pores to form [60]. In fact, by increasing the impregnation ratio of the activating agent, more pores would be created. The impregnation ratio increased, the concentration of ZnCl2 attached to the sample surface increased, resulting in a more violent activation reaction, which had a good effect on porosity development. In this study, based on the general results, it can be concluded that RFSFAC treated with ZnCl2 is better than that treated with KOH. This is the same result as previously reported by D. Anis, et  Table 4 gives an overview of activated carbon characteristic results in this study, and some of the results of previous studies.

Discussion
The characteristics of activated carbon are highly dependent on the precursors used, the impregnation ratio, the carbonization time, and the carbonization temperature [59]. In other words, the use of different raw materials and activation treatments can result in activated carbons with very different properties. The RFSFAC6, with a ZnCl 2 impregnation ratio of 1:5, surpasses all other samples (seen in Table 3). Using ZnCl 2 as an activating agent, RFSAC formed a relatively stable carbon structure below 400 • C, and then began to deteriorate the carbon matrix, resulting in porosity between 400 and 500 • C. At higher temperatures, ZnCl 2 has been vaporized and decomposed into zinc and chlorine, which could cause more pores to form [60]. In fact, by increasing the impregnation ratio of the activating agent, more pores would be created. The impregnation ratio increased, the concentration of ZnCl 2 attached to the sample surface increased, resulting in a more violent activation reaction, which had a good effect on porosity development. In this study, based on the general results, it can be concluded that RFSFAC treated with ZnCl 2 is better than that treated with KOH. This is the same result as previously reported by D. Anis, et al. [61]. Table 4 compares the textural properties of the optimal RFSFAC prepared in the present study (RFSFAC6) with those of 10 other activated carbon materials reported in the literature. As shown, RFSFAC6 has only a moderate surface area (456 m 2 /g) and pore size (3.4 nm) but has the highest carbon content (80.05 at.%) of all the considered materials. According to the conventions of the International Union of Pure and Applied Chemistry, pore sizes ranging from 2 to 50 nm (mesopores) provide an effective absorption performance for many contaminant materials [62]. For example, RFSFAC6 with a mesopore size of 3.4 nm has significant potential as an absorbent material for wastewater treatment and water purification purposes. Furthermore, with its high carbon content of 80.05 at.%, it also has significant promise for use as a pack carburizing medium in heat treatment processes [63].

Conclusions
This study has prepared fine activated carbon (FAC) from rubber fruit shells (RFS) using two different activating agents (KOH and ZnCl 2 ) and three different impregnation ratios (1:3, 1:4, and 1:5). The various products have been systematically characterized and compared by thermogravimetric analysis (TGA), energy dispersive X-ray spectrometry (EDS), X-ray diffraction spectroscopy (XRD), and scanning electron microscopy (SEM). In general, the results have shown that ZnCl 2 outperforms KOH as an activator in terms of a higher specific surface area and carbon content. Furthermore, the activation performance of ZnCl 2 improves with an increasing impregnation ratio. For the highest impregnation ratio of 1:5, the ZnCl 2 -activated RFSFAC has a BET surface area of 456 m 2 /g, an average pore size of 3.44 nm, a nitrogen absorption capacity of 150 cm 3 /g, a 70% mesoporous structure, and a carbon content of 80.05 at.%. Overall, the results indicate that RFS has significant potential as a low-cost, abundant, and effective precursor for the preparation of FAC with high carbon content.