Composite zeolite beta catalysts for catalytic hydrocracking of plastic waste to liquid fuels

The conversion of model waste plastic mixture into high-value liquid product was studied in the presence of hydrogen and composites of zeolite beta catalysts. For the sake of comparison, the conversion of actual waste plastic mixture and high-density polyethylene was also carried out. The composite zeolite beta catalysts were synthesized using a range of silica-to-alumina ratios, alkali concentrations, and hydrothermal treatment times. SEM, EDX, XRD, N2-BET, FTIR, and py-FTIR were used for the characterization of the catalysts. The catalytic experiments were conducted in a 500 ml stirred batch reactor at 20 bar initial cold H2 pressure and the temperature of the reaction was varied between 360 and 400 °C. The two composite catalysts, BC27 and BC48, prepared without alkali pretreatment were found to be the most suitable catalysts. With BC27 and BC48 at 400 °C, 93.0 wt% conversion was obtained with actual plastic mixture and the liquid yield exceeded 68.0 wt%. Experiments with the regenerated catalysts showed their performance comparable to the fresh catalysts.


Introduction
Conventional methods used for the disposal of plastic wastes such as landfilling and incineration are not desirable from the environmental viewpoint. Landfilling ends in the accumulation of a large volume of plastic waste over an extended period of time [1,2]. Not only is landfilling an environmental burden, but it also wastes the useful energy contents of the plastics [1,[3][4][5]. Incineration, on the other hand, results in the emissions of toxic pollutants into the environment [3,4,[6][7][8][9]. Chemical recycling of plastic wastes into functional products is perhaps the most preferred method of waste plastic management [10][11][12][13]. In one of the chemical recycling methods, the waste plastics are converted, in the presence of hydrogen, into high-quality liquid fuels. The long-chain plastic molecules are transformed into smaller more useful products of gasoline and diesel range [5]. The efficiency of this hydroconversion or hydrocracking process is further enhanced by the use of a catalyst that considerably reduces the process reaction temperature, while increasing the selectivity of the products. In the literature, various catalytic materials are used for the hydrocracking of plastic materials. Several researchers employed zeolites including HZSM-5 [10,[14][15][16][17][18][19][20][21], HY [10,22], and HUSY [23][24][25]. These zeolite catalysts showed quite favorable activity, but the product obtained comprised mostly gases pertaining to the microporous nature of these catalysts [26,27]. The catalysts that contain mesopores such as Al-SBA-15 [28], Al-SBA-16 [25,28,29], and Al-MCM-41 [10] are also used in the literature though by only a few researchers. The mesoporous catalysts demonstrate excellent diffusion of heavier molecules and the product obtained consists of higher liquid contents. However, mesoporous catalysts show weak cracking ability due to their weak acidic nature [30,31]. A micro-mesoporous composite catalyst is, therefore, considered to accommodate the advantages of each of the two microporous and mesoporous characters. The combination provides the initially cracked large polymer segments an easy access to the active sites of the catalyst and thereby 9 Page 2 of 13 increases the activity of the microporous zeolite. Moreover, mesopores allow the large molecular weight molecules to reach in the gas phase as reaction product. A more liquid containing and more useful product is thus resulted. Composites of mesoporous catalysts with zeolite nanoseeds, for the plastic hydrocracking, are used by Munir and Usman [28,29]. However, the results obtained over these catalysts were not satisfactory. Composites of zeolites can also be prepared by introducing mesoporosity in the preformed (previously synthesized) zeolites. This approach was used in our previous work for the synthesis of micro-mesoporous composites of commercial HUSY with SBA-16 [25]. The composites of USY catalysts showed promising results and demanded additional study over the composites of other zeolites.
In the present work, commercial zeolite beta (CP811C300) is used for the synthesis of micro-mesoporous composite catalysts. Zeolite beta is a large pore crystalline aluminosilicate material. Its highly acidic nature and distinct pore structure make it able to be applied in fluid catalytic cracking [32], hydroforming [33], etc. In the current study, zeolite beta and its in-house synthesized composite catalysts are used for the catalytic hydrocracking of model waste plastic mixture, HDPE, and actual waste plastic mixture. Additional experiments are performed for the evaluation of catalyst stability. To our knowledge, these types of catalysts have never been used for the catalytic hydrocracking of plastics.

Catalyst preparation
8.28 g of a mixture of pluronic F-127 (Sigma-Aldrich) and pluronic P-123 Sigma-Aldrich) was added into 1 M HCl solution and the solution was stirred for 3 h. 0.1063 g of NH 4 F (≥ 98.0% purity, Sigma-Aldrich) was then added into the solution. Separately, 1.5 M NaOH solution was prepared and 3.7 g of powdered zeolite beta (CP811C300, Zeolyst) was added to it and the solution was stirred for 1 h at 60 °C. A third solution was prepared by adding 4.9 g of aluminumisopropoxide (AIP, ≥ 98.0% purity, Sigma-Aldrich) into 1 M HCl solution. The resulting solution was stirred for 4 h at room temperature to have a homogeneous solution. The first two solutions were collected together and the produced solution was stirred continuously for 15 min. 40 g of tetraethylorthosilicate (TEOS, 98.0% purity, Sigma-Aldrich) was then added into this solution. The solution was again stirred for 4 h at 50 °C. After that, the third mixture was poured into it and the final mixture was then continuously stirred for 24 h. For the hydrothermal treatment, the mixture was charged into a stainless steel autoclave and crystallized at 110 °C in an oven for 27 h. The autoclave was lined with Teflon to avoid any interaction of the stainless steel with the mixture contents. Before transferring the mixture to the autoclave, the pH value of 4.0 was adjusted. Ammonia solution (33.0% NH 3 , Riedel-de-Haën) was used to regulate the pH of the mixture. The final product was centrifuged while washing several times with doubly distilled water. The product was then dried in an oven for 20 h at 100 °C and later calcined in a muffle furnace for 5 h at 600 °C, with a heating ramp of 2 °C/min. The synthesized catalyst had a sodium form. To achieve the proton form, the ion-exchange procedure was performed. This procedure was done by stirring the catalyst in 100 ml of 3 M ammonium acetate (≥ 98.0% purity, Sigma-Aldrich) solution at 60 °C, under vigorous stirring for 5 h. The ammoniated catalyst was then filtered and washed with doubly distilled water. Later, it was dried in an oven at 100 °C for 12 h. The catalyst was again calcined at 600 °C for 4 h in a muffle furnace. The final catalyst was called as BC11.1. The catalyst BC5.7 was synthesized using the same procedure, however, the TEOS/beta ratio was set as 5.7 (wt/ wt). BC0.7 and BC27 were synthesized with 0.7 M and 0 M NaOH (no sodium hydroxide), respectively, keeping all the other variables as constant. BC48 was produced from the same method as that of BC27, however, in this case, the duration of the hydrothermal treatment was 48 h in contrast to 27 h used for all the other catalysts.

Catalyst characterization
Field emission scanning electron microscope (Mira 3 TES-CAN) was used for the SEM images. The catalyst samples were sputtered with carbon before taking their micrograph. The BET surface areas, pore size distributions, and nitrogen adsorption-desorption isotherms at 77.3 K were measured using Micromeritics TriStar II-3020. The catalyst samples were degassed at 200 °C for 2 h under vacuum using Micromeritics Smart Prep (Programmable Degas System), before the analysis. PANanalytical Empyrean diffractometer (Cu-Kα X-ray radiations) with 0.013° step size and 8.67 s step time was used for small-angle XRD patterns of the calcined catalysts. The 2θ range covered was 0.5°-4°. PANalytical X'Pert diffractometer was used for wide-angle XRD that using the Ni-filtered Cu-Kα radiation (λ: 0.145 nm) and with the scanning step of 0.02° per step for the 2θ range of 6°-90°. Infrared (IR) spectra of the catalysts were obtained using JASCO, FTIR-4100. In the FTIR analysis, pellets made out of 98% of KBr and 2% of catalyst sample were used. The 400-4000 cm −1 range was selected for the analysis. Py-FTIR (Pyridine, ≥ 99.0%, Sigma-Aldrich) analysis was employed to observe the character of the acid sites. The same FTIR machine mentioned above was used for the Py-FTIR and 1400-1700 cm −1 was set as the range of analysis.

Catalytic experiments
Catalytic hydrocracking of the model plastic mixture that consisted of 40 wt% HDPE (ρ = 0.952 g/cm 3 , Sigma-Aldrich), 10 wt% LDPE (ρ = 0.918 g/cm 3 , MP = 100-125 °C, Sigma-Aldrich), 30 wt% PP (MW = 250,000 g/mol, ρ = 0.9 g/cm 3 ), and 20 wt% PS (MW = 192,000 g/mol) was carried out for the evaluation of activity and selectivity of the synthesized catalysts. The experiments were performed in a 500 ml high pressure stirred autoclave reactor (Parr Instrument Co.). A schematic diagram of the reactor is shown in Fig. 1. The details of the experimental setup can be found in Munir [34].
10 g of plastic and 0.5 g of catalyst were loaded in the reactor vessel. The catalyst was dried previously in oven at 130 °C for 30 min to remove the moisture contents. Initial H 2 pressure of 20 bar was then given to the reactor. The temperature of the reactor was allowed to increase till it reached the reaction temperature. The temperature was raised at the rate of 4.6 °C/min. Residence time of 60 min was given at the reaction temperature. The reactor was then allowed to cool down to the room temperature. The gas release valve was crack-opened to collect the gaseous products. The reactor vessel was then removed and the liquid and solid products were collected. The products were mixed with n-heptane (≥ 99.0% purity, Sigma-Aldrich) and the yield of the n-heptane solubles was regarded as the oil yield. The n-heptane insolubles were then solubilized with tetrahydrofuran (≥ 99.0% purity, Sigma-Aldrich). The sum of the yields of the THF solubles and the n-heptane solubles was collectively called as liquid yield. The THF insoluble fraction which might consist of spent catalyst, coke, and unconverted plastic, if any, was dried in an oven and weighed. The conversion for the hydrocracking reaction was defined on the basis of this remaining solid. The yield of the gaseous product was obtained by weighing the reactor at the start (before pressurizing the reactor with hydrogen) and at the end of an experiment (after removing the gases). The term yield was defined as weight of a quantity to the 100 g of plastic feed fed to the reactor at the start of the experiment. The recovery was calculated as 100 minus the sum of the gas, liquid, and solid yields.
Hydrocracking reactions with model plastic mixture were carried out at three temperatures, namely, 360 °C, 375 °C, and 400 °C. The reactions with HDPE (as it is more difficult to degrade compared to LDPE, PP, and PS) and actual waste plastic mixture and the reactions for testing the stability of the catalysts were performed at 400 °C. Actual waste HDPE was washed, cleaned, and dried shampoo bottles, LDPE was unused plastic bags used for the purpose of shopping, PP was unused food containers, and PS was unused tea cups.

Characterization of catalysts
The SEM micrographs of the catalysts are shown in Fig. 2. The micrograph of the commercial beta zeolite (B300) shows ball-like distinct particles that illustrate the characteristic crystals of zeolite beta [35,36]. The BC11.1 catalyst shows only a few discrete particles of zeolite beta along with large rough surface agglomerates of irregular shaped morphologies. These rough large agglomerates represent amorphous mesoporous portion. As this catalyst is prepared by the desilication of zeolite beta with 1.5 M NaOH solution, it seems that desilication has resulted in the destruction of the parent zeolite beta structure. The micrograph of the BC5.7 catalyst displays morphology similar to that of the BC11.1 catalyst. However, here, compared to BC11.1, more regular shaped zeolite beta particles are present. This can be explained on the basis that lower TEOS/beta ratio was used in the preparation of BC5.7. The morphology of BC0.7 shows higher content of individual crystals of zeolite beta. The BC0.7 catalyst is desilicated with lower molarity of NaOH solution as compared to BC11.1. The lower molarity of NaOH solution resulted in the formation of less distorted structures of zeolite beta. Along with zeolite beta particles, there are irregular shaped aggregates that represent amorphous mesoporous phase. More regular shaped discrete zeolite beta crystals are shown by BC27. As this catalyst was prepared in 0 M NaOH solution (in the absence of alkali treatment) and there was no desilication, hence no destruction of the zeolite structure is observed. Also, there are some irregularly shaped masses that represent mesoporous content. Compared to BC27, BC48 shows increased amounts of aggregated structures and higher mesoporous silica. Higher hydrothermal treatment time given to BC48 seems to increase the mesoporous portion to a considerable extent. Figure 3 shows the N 2 adsorption-desorption isotherms of the catalysts. The commercial zeolite beta catalyst displays type I isotherm, that is a characteristic isotherm of the microporous zeolitic materials [37]. The isotherms of all the other beta modified catalysts such as BC11.1, BC5.7, BC0.7, BC27, and BC48 are similar to that of the parent beta catalyst in the region of lower relative pressure. All these catalysts are showing type IV isotherm with characteristic H2 hysteresis loop [38]. The nature of the isotherms demonstrates the formation of the composite assembly [39] of these catalysts having micropores of zeolite beta present alongside mesoporous silica.
The pore size distribution of the catalysts is depicted in Fig. 4. It is observed that the BC11.1 catalyst is characterized by broad pore size distribution with most of the pore sizes of 3.62 nm, 4.15 nm, and 4.75 nm. On the other hand, the BC5.7 and BC0.7 catalysts show bimodal pore size distribution. The former with the lower TEOS/beta ratio has a sharp peak indexed at 3.62 nm and a small peak at 5.1 nm, whereas for the latter, most of the pore sizes are of 5.43 nm with a smaller peak indexed at 3.62 nm. BC27 has the majority of pore sizes of 3.63 nm and a few of 2.8 nm. With a decrease in molarity of NaOH solution, there is a trend towards more uniform pore size with bimodal pore size distributions. The catalyst prepared with 0 M NaOH solution (BC27) has the highest content of micropores along with the mesopores as compared to the other composite catalysts. In the desilicated composite catalysts, however, the parent zeolite beta has also developed some mesopores due to the surface defects created by the extraction of silica from the structure. BC48 has a narrow pore size distribution with a sharp peak indexed at 3.65 nm and two smaller peaks at 2.65 nm and 5.19 nm. The pore size distribution of BC27 and BC48 are similar and both the catalysts have nearly the same distribution around 2.65 nm and 3.65 nm. However, in the case of BC27, there is an increased amount of micropores, whereas BC48 has a significant quantity of mesopores. It is, therefore, revealed that an increase in hydrothermal treatment time has resulted in a decrease of micropore quantity and an increase in the amount of mesopores with larger pore size.
The structural properties of the catalysts from nitrogen physisorption are shown in Table 1. The highest surface area is found in BC27 that is followed by BC48. Both of these catalysts are composite catalysts of zeolite beta without any desilication treatment. The surface area of all the desilicated catalysts (BC11.1, BC5.7, and BC0.7) is lower than that of the parent beta catalyst. Among the composite catalysts, the highest micropore volume is given by BC27 followed by BC48. All these results strengthen the fact that the structure of zeolite beta in the desilicated composites is distorted, whereas in BC27 and BC48, the structure of zeolite beta is intact in the final composite catalyst. Therefore, zeolite beta along with the mesoporous silica have coherently contributed towards the increase in the surface area  of these catalysts. The highest BJH pore volume is found in BC48. This catalyst has found to contain the highest mesoporous content confirmed also by the other characterization techniques. Figure 5 shows the small-angle X-ray analysis of the catalysts. All the composite catalysts exhibit a well-resolved peak at 2θ value of around 0.78 (0.88 in the case of BC0.7) that corresponds to (100) reflection. A tiny peak is present in nearly all the catalysts at 2θ value of around 0.98 (relatively strong in BC27 and BC48 and weak in the other catalysts) that correspond to (110) reflection [40]. All the catalysts possess many small peaks at 2θ value of 1.10-2.90 which are not well resolved and difficult to differentiate. The results indicate the presence of mesostructure with low order [41,42] that might be attributed to higher pH of the hydrogel mixture before the hydrothermal treatment in the synthesis step. The pH of the mixture was maintained to a value of 4 before the hydrothermal treatment to prevent the chances of aluminum leaching. Low-order structure could also be resulted from the co-existence of cubic and hexagonal mesostructures in the catalysts.
The wide-angle X-ray diffractogram of the commercial zeolite beta shown in Fig. 6 presents well-resolved peaks that are characteristic features of a highly crystalline zeolite beta. The diffractograms of the composite catalysts with desilication treatment (BC11.1, BC5.7, and BC0.7) indicate the destruction of highly crystalline structure of the zeolite beta in these composites. As a result, these catalysts are showing the diffraction pattern similar to that of an amorphous catalyst. In other words, the zeolite beta structure is appeared to collapse significantly by the desilication and the resulting diffraction patterns of these catalysts are contributed by the mesoporous silica content. The decrease in the crystallinity is also observed in the catalysts prepared without desilication due to the introduction of mesoporosity and not due to the damage to the crystal structure of the catalysts by desilication. Among all the composite catalysts, Table 1 Structural properties of the zeolite beta composite catalysts t h is hydrothermal treatment time, S g is surface area using BET method, S mi is micropore area obtained by t-plot, BJH S g is BJH adsorption cumulative surface area of the pore between 17 Å and 3000 Å width, v mp is micropore volume obtained by t-plot, BJH v p is BJH adsorption cumulative volume of the pore between 17 Å and 3000 Å width, and BJH d p is BJH adsorption average pore diameter  BC27 is found to be the most crystalline catalyst. Increasing time of hydrothermal treatment results in the degradation of the crystalline structure of BC48 compared to BC27 indicating the presence of better mesostructure in BC48. This fact is also confirmed by the results obtained with SEM and nitrogen physisorption. Figure 7 shows the Py-FTIR spectra of the catalysts. All the catalysts except BC0.7 show an intensified band at 1628 cm −1 that corresponds to pyridine association with strong Lewis acid sites [43,44]. BC11.1, BC48, and BC27 exhibit less intensified bands at 1545 cm −1 and 1485 cm −1 that indicate the presence of Brønsted acid sites [43] and Lewis + Brønsted acid sites, respectively [40,45]. The B300 and BC0.7 catalysts have a band at about 1540 cm −1 assigned to Brønsted acid sites [43]. BC0.7 is found to contain the lowest amount of acid sites. Out of all the catalysts, mesoporous composites BC48 and BC27 have shown to have the highest amount of acid sites more than B300.
The FTIR spectra of the catalysts representing the atomic level connections of the chemical bonds in the catalysts are shown in Fig. 8. A transmission band at 557 cm −1 exists in B300, BC48, and BC27 that corresponds to the vibrational mode of a typical zeolite beta structure having 5 or 6 membered rings of T-O-T in zeolites [36]. This band is almost absent in the other catalysts resulted from the desilication by NaOH solution suggesting damage to the zeolite beta crystalline structure to some extent. All the catalysts exhibit the transmission bands at 464 cm −1 and 1045 cm −1 that are attributed to T-O bond stretching vibration and bending vibration, respectively [45]. Another significant band is observed in all the catalysts at 800 cm −1 that corresponds to T-O-T bond symmetric stretching [46]. The band at 950 cm −1 is assigned to the stretching vibration of Si-OH [47,48]. There is a broad peak in each catalyst from 1034-1250 cm −1 that is assigned to the asymmetric stretching of Si-O-Si bond [20]. Furthermore, each catalyst exhibits a broad band at 3677 cm −1 which is attributed to the bond vibration of the terminal silanol group [40]. Another important band is also observed at 1663 cm −1 which indicates -OH bond flexural vibration [46].

Catalytic hydrocracking performance of the catalysts
The results of the hydrocracking experiments with model plastic mixture, actual waste plastic mixture, and HDPE are discussed in the following sections. On average greater than 95% (by weight), recovery was obtained. All the results of experimentation are tabulated in Table S1. Figure 9 shows the results of experimentation with model plastic mixture at three different temperatures (360 °C, 375 °C, and 400 °C). It is observed that at the reaction temperature of 360 °C, the lowest reaction temperature, BC48 delivered the highest conversion with the highest liquid and oil yields, whereas BC27 closely followed it. Both BC27 and BC48 exhibited much better activity and selectivity towards  BC0.7, c BC27, d BC5.7, e BC11.1, and f BC48   Fig. 8 FTIR spectra of the catalysts: a B300, b BC11.1, c BC5.7, d  BC48, e BC0.7, and f BC27 the liquids in comparison to all the other catalysts employed in the study. Clearly, the commercial zeolite beta (B300), due to its microporous nature, has shown greatly reduced activity and selectivity towards the liquid. The two micromesoporous composite catalysts, BC27 and BC48, were synthesized without desilication of the parent zeolite. Alkali treatment perhaps damaged the crystal structure and aided in the loss of the activity, whereas no-desilication maintained the microporous crystallinity of the composite catalysts and resulted in improved performance of the catalysts. Moreover, increase in the hydrothermal treatment time resulted in higher mesoporous area of BC48 than that of BC27. The increased mesoporous area facilitated the improved diffusion of the initially cracked higher molecular weight polymeric fragments and the cracked liquid products through the pores of the catalysts. An enhanced activity and desired selectivity of BC48 catalyst over BC27 catalyst was, therefore, possible. Additionally, as observed in Table 1, both BC27 and BC48 have the highest surface area, in fact, much larger than the surface area of all the other catalysts. Also, they have appreciable surface due to both the micropores and the mesopores compared to rest of the catalysts where only one of the areas has significant value. As an example, for BC27, the total surface area is 775.4 m 2 /g and microporous and mesoporous surfaces are 309.1 m 2 /g and 180.7 m 2 /g, respectively. On the other hand, for B300, the total surface area is 508.1 m 2 /g, while the micro and meso surface areas are 465.4 m 2 /g and 43.44 m 2 /g, respectively. For BC5.7 having 475.5 m 2 /g total surface area, micropore area is 51.79 m 2 /g and mesopore area is 192.2 m 2 /g. The presence and perhaps better distribution of both the micropores and mesopores seem the reason for the increased activity of the BC27 and BC48 catalysts.

Reactions with model plastic mixture
At 375 °C, again the same two catalysts BC27 and BC48 showed the increased conversion and liquid yield. However, at this temperature the parent B300 catalyst also showed improved performance, though, the catalyst produced the highest gas yield. High gas yields with B300 might be explained by its dominant microporous character. The desilicated catalysts still showed unsatisfactory performance. As mentioned before, this last result might be attributed to the structural damage to the parent zeolite in the desilicated catalysts which is also evident from the characterization of the alkali-treated catalysts. The structural damage to the parent zeolite may suggest that the performance of the desilicated catalysts corresponds only to the mesoporous content of these catalysts.
At the reaction temperature of 400 °C, the parent zeolite beta (B300), BC27, and BC48 have shown similar activities. However, BC27 and BC48 catalysts produced the highest amount of liquids whereas B300 provided higher gas yields. Moreover, the desilicated catalysts maintained their poor performance with respect to both the activity and the liquid selectivity.
The results of gas chromatography of the oil fractions obtained at three reaction temperatures are shown in Fig. 10. It is found that at each temperature, the B300 catalyst showed increased selectivity for the gasoline product. It may correspond to the micropores present in B300 that allowed low molecular weight molecules of gasoline range to leave in the gas phase relatively easily. The BC27 and BC48 catalysts also produced increased gasoline content. Gasoline fraction Fig. 9 Results of the catalytic hydroconversion reactions of model plastic mixture over different catalysts. 500 ml autoclave reactor, 20 bar initial cold hydrogen pressure, 60 min residence time, and 20:1 feed-to-catalyst ratio (by weight) of these two catalysts is close to that obtained with B300, at the higher reaction temperatures of 375 °C and 400 °C. With increase in reaction temperature, the light diesel component over BC27 and the heavy diesel component over BC48 were converted into gasoline. Increase in reaction temperature might have resulted in the breakdown of heavy molecular chains of light and heavy diesel components. Generally, all the desilicated catalysts produced much lower gasoline fraction but greater diesel fractions than that of B300, BC27, and BC48.

Reactions with actual waste plastic mixture
Both BC48 and BC27 catalysts were found the most active and selective catalysts in the hydrocracking experiments with model plastic mixture. These two catalysts were, therefore, further exploited to study their cracking performance with actual waste plastic mixture. The experiments were carried out under the reaction conditions of 400 °C, 20 bar initial cold H 2 pressure, 60 min reaction time, and 20:1 (by weight) feed-to-catalyst ratio.
The results of experimentation with waste plastic mixture and their comparison with model plastic mixture (and HDPE) are shown in Fig. 11. It is found that both BC27 and BC48 provided nearly the same conversion. However, BC27 showed a slightly improved performance with respect to liquid and gas yields. It is observed that the conversion of BC27 and BC48 was only slightly decreased when waste plastic mixture was employed compared to when experiments were conducted with HDPE or model plastic mixture. However, a slight improvement in the liquid yield with corresponding decreased amounts of gases is observed with actual waste plastic mixture. These results show that the two catalysts are appropriate in handling the waste plastic material. The performance of the catalysts may also be dedicated to the presence of hydrogen which, in the presence of a catalyst, can carry out hydrotreating of the impurities [17] that may hinder the performance of the catalysts.
The gas chromatography results (Fig. 12) show that gasoline yield is somewhat decreased with waste plastic mixture in comparison to model plastic mixture. Comparing BC27 and BC48, BC27 has shown better gasoline and diesel yields with the actual waste plastic mixture. Higher gasoline content of Fig. 10 Results of GC analysis of the n-heptane soluble liquids obtained by the catalytic hydroconversion of model plastic mixture over different catalysts. 500 ml autoclave reactor, 20 bar initial cold hydrogen pressure, 60 min residence time, and 20:1 feed-to-catalyst ratio (by weight) Fig. 11 Results of the catalytic hydroconversion reactions of indicated plastic materials over BC27 and BC48 catalysts. 500 ml autoclave reactor, 20 bar initial cold hydrogen pressure, 60 min residence time, and 20:1 feed-to-catalyst ratio (by weight) 9 Page 10 of 13 64.3 wt% is produced by BC27, while BC28 yields 59.7 wt% gasoline.

Hydrocracking reactions with HDPE
Hydrocracking reactions with HDPE over BC27 and BC48 under reaction conditions of 400 °C, 20 bar cold H 2 pressure, 60 min reaction time, and 20:1 (by weight) feed-to-catalyst ratio are shown in Fig. 11. The results revealed that both catalysts again yielded nearly similar conversion of about 100% and again BC27 showed slightly improved performance with regard to gas and liquid yields. The higher liquid yield of 58.8 wt% and the lowest gas yield of 33.2% were produced by the BC27 catalyst. It is found that both catalysts for the reactions of HDPE yielded nearly the same conversion, but lower amount of liquid yield, and significantly higher gas yield compared to their corresponding reactions with model plastic mixture. This is reasonable and can be explained on the basis that the model plastic mixture contains significant amounts of PS, PP, and LDPE which are expected to produce higher liquid products [5]. Moreover, the interaction among the various plastics can result in the formation of higher liquid content obtained by the hydrocracking of model plastic mixture [49].
The GC analysis of n-heptane solubles for BC27 shows that the amount of gasoline obtained with HDPE is reduced to 57.8% in comparison to 70.53% with model plastic mixture, correspondingly higher yields of light diesel and heavy diesel are obtained with HDPE.

Stability study of the catalysts with and without regenerating the catalysts
Hydrocracking reactions with coked (dried spent) catalysts The stability of the catalysts was analyzed using the spent (coked) catalysts for the hydrocracking reactions with model plastic mixture. The spent catalyst was obtained from an earlier experiment with model plastic mixture using 500 ml autoclave, 60 min of residence time, 400 °C of reaction temperature, and 20 bar initial cold hydrogen pressure. The spent catalyst was subjected to drying in an oven for 30 min at 120 °C. The dried spent catalyst was mixed with the fresh catalyst in 1:1 ratio by weight to compensate the loss of the used catalyst and to maintain the same feed-tocatalyst ratio. The spent catalyst was then employed for the cracking reaction with model plastic mixture under the same reaction conditions as discussed above for the case of an earlier reaction. The results obtained are shown in Fig. 13.
It is found that BC27 and BC48 produced significantly lower conversions in the stability runs as compared to their reactions over the fresh catalysts. Also, the liquid yield and the gas yield obtained over both the coked catalysts is lower to that obtained with the fresh catalyst. Among the two catalysts, BC27 produced higher conversion, 72.2wt%, and higher liquid yield, 59.9wt% suggesting BC48 was more prone to coking. A catalyst with higher mesoporosity (BC48) allows the greater production of heavier compounds thus might result in increased coke formation.
The gas chromatography analysis of n-heptane soluble liquids from the stability reactions is displayed in Fig. 14. When compared to the reactions over fresh catalysts, it is found that the spent catalysts are less selective towards gasoline than their corresponding fresh catalysts. Comparing the BC27 and BC48 catalysts, it is observed that BC27 produced higher gasoline content of 41.6% than that of BC48, which is more selective towards heavy diesel.
Hydrocracking reactions with regenerated (calcined spent) catalysts The stability of the catalysts was further analyzed using regenerated catalysts with model plastic mixture. The spent catalysts were calcined in air to remove the carbo- Fig. 12 Results of GC analysis of the n-heptane soluble liquids obtained by the catalytic hydroconversion of indicated plastic materials over BC27 and BC48. 500 ml autoclave reactor, 20 bar initial cold hydrogen pressure, 60 min residence time, and 20:1 feed-to-catalyst ratio (by weight) Fig. 13 Results of the stability test of BC27 and BC48 catalysts for the catalytic hydroconversion reaction of model plastic mixture. 500 ml autoclave reactor, 20 bar initial cold hydrogen pressure, 60 min residence time, and 20:1 feed-to-catalyst ratio (by weight) naceous deposits from their surface. Each of the calcined spent catalysts was mixed with equal amount by weight of the corresponding fresh catalyst and the experiments were performed under the same reaction conditions as discussed above. The results of the hydrocracking reactions over the regenerated catalysts are shown in Fig. 13. Generally, both the catalysts yielded comparable conversion and the product yields to that of the fresh catalysts. The regenerated BC48 catalyst produced relatively higher gas yield and lower liquid yield than its corresponding fresh catalyst. The reason might be assigned to the increase in active sites of the catalysts due to calcination that decomposed the coke deposited on the active sites. Also, some sintering of the particles might occur reducing the average pore size of the catalysts thereby generating increased amounts of gases with reduced quantities of liquids.
The gas chromatography of the n-heptane solubles revealed that the regenerated catalysts yielded rather decreased amount of gasoline compared to the fresh catalysts. However, they provided significantly improved amount of gasoline compared to the coked catalysts. Coked catalysts provided significantly increased amount of heavier liquids.

Conclusion
The results of the catalyst characterization confirmed the formation of micro-mesoporous composite materials. The catalysts (BC11.1, BC5.7, and BC0.7) prepared by the desilication of the parent zeolite beta performed poorly in the hydrocracking reactions. On the other hand, the catalysts (BC48 and BC27) prepared without alkali pretreatment resulted in significantly greater liquid yields, lower gas yields, and higher plastic conversions. For the two catalysts, the GC analyses of the n-heptane solubles also showed the enhanced selectivity towards gasoline. Comparing BC48 and BC27, it is observed that overall BC48 performed better than BC27 as it produced more liquid yield and higher conversion, especially at reduced temperatures. GC analysis of n-heptane soluble also showed increased selectivity of BC48 over BC27 towards gasoline. The appropriate distribution of micropores and mesopores in the former might be the reason behind its better action.
Additional experiments with actual waste plastic mixture showed the comparable performance of these catalysts with the model plastic mixture. With high-density polyethylene, however, lower liquid yields and higher gas yields were obtained. When tested for the stability of the catalysts, coked catalysts yielded far less conversion and were selective in producing heavier liquid fractions, whereas regenerated (by calcination in air) catalysts showed comparable results to the fresh catalysts apart from giving somewhat reduced amount of gasoline. Fig. 14 Results of GC analysis of the n-heptane soluble liquids obtained during the stability test of BC27 and BC48 catalysts for the catalytic hydroconversion reaction of model plastic mixture. 500 ml autoclave reactor, 20 bar initial cold hydrogen pressure, 60 min residence time, and 20:1 feed-to-catalyst ratio (by weight)