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Article

Synthesis of Hydroxy Sodalite from Coal Fly Ash for Biodiesel Production from Waste-Derived Maggot Oil

1
Department of Chemical Engineering, Cape Peninsula University of Technology, Cape Town 7535, South Africa
2
Department of Mechanical Engineering, Cape Peninsula University of Technology, Cape Town 7535, South Africa
3
Environmental and Nano Science Research Group, University of Western Cape, Cape Town 7535, South Africa
*
Author to whom correspondence should be addressed.
Catalysts 2019, 9(12), 1052; https://doi.org/10.3390/catal9121052
Submission received: 3 September 2019 / Revised: 25 November 2019 / Accepted: 26 November 2019 / Published: 11 December 2019
(This article belongs to the Special Issue Catalytic and Functional Materials for Environment and Energy)

Abstract

:
Zeolites are aluminosilicate crystalline materials known for their unique characteristics, and have been prominent for nearly half a century due to their wide and important industrial applications. The production of zeolites, however, remains a challenge due to the high cost of commercial reagents conventionally used as feedstocks. In the current study, hydroxy sodalite (HS) zeolite samples were synthesised from coal fly ash feedstock by a direct hydrothermal synthesis method. The effects of hydrothermal crystallisation synthesis time on phase crystallinity, crystal size, and morphology of the formed HS were investigated. The prepared samples were characterised using XRD, SEM, EDS and FT-IR techniques. The XRD results of the samples prepared with varying synthesis times confirmed the formation of HS from low to high phase purity and crystallinity from 11 to over 98%. The SEM results reflected gradual variation in crystal morphology, of which highly crystalline HS samples were associated with hexagonal-cubic and cubic-platelet crystals. The FTIR, depicting zeolite characteristics of T–O and T–O–T stretching vibrations in the molecular framework, further confirmed the formation of HS zeolites for samples obtained above the 24-h synthesis time. These zeolite samples were then evaluated for their catalytic activities in the conversion of maggot oil to biodiesel. The application of the various hydroxy sodalite samples for the transesterification of maggot oil yielded up to 84.10% biodiesel (FAME) with physicochemical properties that were in compliance with the biodiesel specification standards. This study investigated the novel use of a coal fly ash-derived, heterogeneous HS catalyst in biodiesel production from maggot oil, and indicates its potential to enhance biodiesel yield and quality upon process optimisation tests.

Graphical Abstract

1. Introduction

Zeolites are aluminosilicate materials that have been known for over 250 years; they occur naturally, but have been synthetically produced on a large-scale due to their wide use in various applications [1]. Zeolites have different mineral phase structures; thus, their synthesis pathway should be tailored to obtain a particular phase for a given application. Molecular sieving, shape selectivity, sorption, and ion-exchange capacity are some of the unique characteristics of zeolites that make their application valuable in important industrial processes [2,3,4]. By the nature of their synthetic pathways, the conventional production of zeolites in large quantities is a challenge associated with the use of commercial compounds as feedstocks, which results in the high cost of zeolite products [5,6].
Although zeolites can be prepared synthetically from various aluminosilicate sources, the above concern motivated this research to explore the use of coal fly ash as an alternative, potentially cheaper and highly-abundant feedstock source, for the preparation of hydroxy sodalite zeolite as a candidate catalyst in biodiesel production. Coal fly ash (CFA) is a solid waste residue resulting from coal burning at power stations, of which over 30 Mt is generated yearly in South Africa (and 800 Mt globally). About 5% is recycled for valuable applications [3,7]. The remainder represents a major pollutant to the environment, and has caused disposal challenges on terrestrial and aquatic ecosystems [8]. Coal fly ash has the potential for reuse as an additive to cement and concrete manufacturing in the construction industry, for soil amelioration in agriculture, as fill material for low lying areas, and in the synthesis of valuable industrial catalysts [3,8]. Other than potentially reducing the cost of zeolites to about one-fifth of that of the commercial zeolite, coal fly ash inherently contains glassy silicon and aluminium in high proportion, such that the feedstock may not necessarily have to come from multiple sources for zeolite synthesis, as compared to zeolite produced from commercial sources [9]. Due to the abundant and continual generation of coal fly ash, it is envisaged that the material is a readily-available source (alumina-silica material) of the precursors required to produce zeolites. Coal fly ash, by virtue of its fine particulate nature, implies a low-energy demand, as it does not require crushing and high-temperature calcination before zeolite synthesis, in comparison to various conventional silica sources [3].
The hydrothermal method is the principal and most commonly-used method for the synthesis of zeolites from coal fly ash [2]. This method involves the dissolution of the aluminosilicate glass contained in CFA in an alkaline solution, which is subsequently converted to the crystalline zeolite phase [10]. Hydroxy sodalite is a hydrophilic zeolite that possesses sodalite cages which are connected in such a way that they enclose small Ǻ size pores [11]. The pores consequently make the application of the material suitable and effective in molecular separation processes and various industrial processes [2]. The small pore apertures imply a large exposed external surface area of HS as a crystalline material, which, when synthesised hydrothermally with alkaline reagents, provides a solid base medium. This property makes HS a suitable catalytic medium, and consequently a solid base catalyst for biodiesel production [9]. As a base catalyst, it is assumed that the use of HS in biodiesel production will achieve high catalytic activity as conventional base homogenous catalysts, the latter being predominant in industrial large-scale production [12]. Moreover, the focus on HS as a solid heterogeneous base catalyst in biodiesel production is gaining much interest due to the challenges of washing, saponification, high water consumption and catalyst separation incurred by the use of the conventional homogenous catalysts [13,14].
Most review papers to date have reported on the synthesis of zeolites (HS) from commercial reagents [9,15]. Although the use of commercial reagents seems to have shortened the synthesis route, their high cost is still reported to increase the overall cost of the final zeolite products [5,9]. Although zeolites have been successfully synthesised from coal fly ash, a challenge remains in obtaining high-quality (pure phase and high crystalline) zeolites [16], which is associated with the synthesis conditions and costs [15,17,18,19]. Zeolites as heterogeneous catalysts are associated with energy-intensive synthesis routes, which are analogous to high synthesis costs. This study was aimed at resource recovery from coal fly ash, to minimise zeolite synthesis costs by investigating the catalyst synthesis under varying conditions for their application in biodiesel production from maggot oil.
Maggot oil, the feedstock of interest in this study, is a waste-derived fat, extruded from the maggots of black soldier fly (BSF) insects that feed on food wastes and convert the wastes into fat. The oil emerges with large availability and is a by-product of the world’s first waste-to-fly factory (AgriProtein) located in Cape Town (South Africa). The oil is applied exclusively for low market value products (animal feed) to date. It was found in previous studies to possess suitable feedstock characteristics for biodiesel production [20,21]. Consequently, literature provides a benchmark for this study to convert the oil into biodiesel, using a HS heterogeneous catalyst. To date, this is the only study in which a coal fly ash-derived, heterogeneous catalyst of HS zeolite form, is synthesised for biodiesel production. The synthesis of HS zeolite is carried out under varying conditions and investigated for application in the transesterification of maggot oil. According to the few existing studies in the literature, maggot oil (biologically known as a lipid of the Hermetia illucens black soldier fly) has been mainly assessed for its fatty acid composition [21] and biodiesel production feasibility using conventional homogenous sodium hydroxide and a sulphuric acid catalyst [20,22]. This study, therefore, focused on the use of the oil for biodiesel preparation using various synthesised heterogeneous HS (zeolites) catalysts. This study further assesses the physicochemical qualities of derivative FAME (biodiesel).

2. Results and Discussion

2.1. Effect of Hydrothermal Synthesis Time on HS Formation

2.1.1. XRD Results

The samples synthesised after 48-h synthesis time showed an almost completely pure phase of HS. These samples were constituted entirely of high HS phase purity and did not contain mixed phases of other crystalline materials (Figure 1).
The above, therefore, indicates that all the mullite (M) and quartz (Q) phases in coal fly ash (CFA) were converted almost fully into the zeolite phase during the ageing and hydrothermal synthesis steps. This demonstrates that ageing at 70 °C for 1.5 h could substitute the high temperature fusion step that is conventionally employed [5,17,23]. The effect of synthesis time was evaluated over different periods (12, 24, 72 and 144 h). Both the S-12 and S-24 samples synthesised hydrothermally for less than 48 h showed almost no crystalline phases of HS (Figure 1). Their XRD patterns displayed rather significant amounts of unconverted and mixed amorphous phases of mullite (M) and quarts (Q). All samples synthesised above 48 h displayed XRD patterns exhibiting the formation of the hydroxy sodalite (HS) phase. The XRD pattern of the sample synthesised after 72 h (S-72) showed high phase purity. In other words, a minimum synthesis time of 48 h at the adopted fixed temperature (140 °C) was necessary for the synthesis of HS from coal fly ash by the direct method. This observation suggests that no synthesis time below 48 h under the given, fixed conditions would be favourable for the synthesis of high phase HS. This finding supports the report by Musyoka et al. [16] favouring the selection of a 48-h synthesis period.
Low HS phase crystallinities of 11% and 18% characterised the samples synthesised after 12 and 24 h respectively (Table 1). By an increase in synthesis time to 48, 72 and 144 h, HS phase crystallinity (as per reference sample) was enhanced to 98%, 100% and 85% respectively.

2.1.2. Effect of Hydrothermal Synthesis Time on Catalyst Morphology

Coal fly ash, the starting material used for the synthesis of HS zeolite, was found to consist entirely of spherical crystals. The produced HS samples, on the other hand, were found to consist of a variety of crystal morphologies, with peculiarities or uniformity observed according to changes in synthesis time. As shown in Table 1, the S-12, exhibited a very low HS phase crystallinity of 11%; this sample was morphologically (Figure 2b) constituted of rough-surfaced, spheroidal crystals.
The above comparison also attests to the insufficient synthesis time for the conversion of amorphous phases of coal fly ash into HS zeolite HS. By increasing the synthesis time to 24 h, the morphology of the resultant S-24 sample, as presented in Figure 2c, evolved into agglomerated thread, ball-like crystals. The hierarchical ball-like morphology is commonly associated with HS zeolite [9]. In spite of the above, the sample in question exhibited a very low HS crystalline phase (18%). It is therefore evident that the morphological representation of HS (or any other zeolite type) through SEM data alone is not always the yardstick reflection of the particular phase identity. A similar observation was reported by Nanganoa et al. [23]. A further increase in synthesis time to 48 h resulted in a uniform and more defined morphology of smooth-surfaced HS crystals in hexagonal-cubic shapes (Figure 2d). With a 72-h hydrothermal synthesis time, a uniform S-72 sample of a morphology comparable to that of S-48 was observed (Figure 2e). In contrast to smooth-surface crystals, the S-72 comprised rough-surfaced, hexagonal-cubic crystals. After a 144-h synthesis time, a hierarchical, cubic-platelet morphology appeared, as depicted in Figure 2f.

2.2. Elemental Composition and Si/Al Ratio of the Synthesised Catalysts

All the synthesised samples were found to consist of similar elemental compositions (Table 2). The main components identified were Si–Al–O (oxides of silicon and aluminium) and oxides of metallic elements. These reflect the composition of a typical zeolite, as reported in literature [10]. The range of the Si/Al ratio obtained for the prepared samples was between 0.8 and 1.4. This corresponds to that of HS zeolite, as reported in literature [11,23]. Although the S-24 sample exhibited the Si/Al ratio closest to that of typical HS zeolite, this sample, as earlier reported in Table 1 and Figure 1, exhibited a low phase purity and low crystallinity of HS. Nonetheless, the relative increase in the Si/Al ratio to 1.2 (as in Table 2), by virtue of the increased synthesis time, was found to be associated with the enhanced morphology of zeolites. Moreover, a dominant direct correlation was observed between the increased Si/Al ratio and the increased HS phase crystallinity (Table 1).

2.3. Fourier Transform Infrared (FTIR) of Synthesised Samples

The FTIR analyses shown in Figure 3 demonstrate the structural configuration of the synthesised samples from coal fly ash starting material (a). The quartz (Q) bands detected in CFA (a) at 1095 cm−1, disappeared after the synthesis steps and shifted towards 975 cm−1 and lower frequencies in the product, indicating successful conversion of the coal fly ash content to zeolites. The band characteristic of the synthesised samples between 420 and 2000 cm−1, including the bulk of vibrational modes observed between 450 and 750 cm−1, represents the characteristics of a typical zeolite structure [15]. As an exception to the above, the samples synthesised below 48-h synthesis time (i.e., 12, 24 h), displayed very weak characteristic bands of the zeolite structure (Figure 3).
HS (Zeolite) vibrational modes began to emerge with an increase in the hydrothermal synthesis time, i.e., 48 h, with an internal bending vibration of T–O (T–Si or Al) partially detected between 450 and 500 cm−1. This was followed by consecutive bands detected at 655 and 750 cm−1, corresponding to double ring vibrations of tetrahedral Si–O and Si–O–Al respectively [23].
Broad transmittance bands of symmetric stretching of T–O–T, associated with external vibrations or linkages between Si–O and Al–O tetrahedral units, were further detected in the region between 905 and 1100 cm−1. This band also demonstrates a balance in the number of Si–O tetrahedral and Al–O tetrahedral units formed. Asymmetric stretching bands of T–O–T, mainly associated with vibrations of Si–O tetrahedral units, were exclusively detected in zeolitic sample of S-48 and S-72 in the region between 1350 and 1562 cm−1. This band for S-72 contained an additional internal vibration of tetrahedral Si–O at 1400 cm−1, indicating the presence of relatively more Si–O tetrahedral units in this sample. Consequently, the S-72 sample, as reported in the EDS analyses shown in Table 2, exhibits the highest Si/Al ratio. A narrow symmetric stretching band was further detected exclusively in sample S-48 and S-72 at 1637 cm−1. This was mostly associated with the formation of the Si–O tetrahedral unit. Beyond the above band, the region further above 1637 cm−1 in all samples synthesised above 24 h was attributed to water molecules attached to sodalite. With an increase in hydrothermal synthesis time, as consecutively indicated (c-d-e-f) in Figure 3, tetrahedral T–O–T frameworks evolved, with the characteristic zeolite structures being optimally exhibited after 48- and 72-h synthesis time.

2.4. Transesterification of Maggot Oil

The maggot oil from Agriprotein (Ltd) is metabolically derived from the maggots of black soldier flies (BSF) upon feeding and growing on food wastes. The highly saturated oil appears as fat at room temperature [24]. It was found to consist of high free fatty acid (FFA) concentration (7.2 mg of KOH/g oil) (Table 3). The high FFA content would have impaired the application of a homogeneous catalyst for the transesterification process. Alternatively, a preliminary esterification process would have been required. The properties of the oil, including their fatty acid profiles, as determined in this study, are shown in Table 3.
All the coal fly ash-based hydroxy sodalite samples, as identified by XRD and FTIR, revealed a potential activity in the transesterification of maggot oil to biodiesel, as reported in Figure 4. An increase in the catalyst synthesis time of S-24, S-48, S-72 and S-144 was overall correlated with an increase in the biodiesel yield of 73.10, 86.00, 81.45, 84.10 and 80.60% respectively. The observed increase in the biodiesel yield was associated with increased HS phase crystallinity (Table 1) and defined morphology (Figure 2). Increased crystallinity, as associated with large crystal size of samples (Table 1), offers a relatively high diffusion constraint on reacting molecules around crystal surfaces, and consequent low yield of biodiesel by catalysts S-12 and ≥S-48 as compared to S-24. Moreover, the increase in biodiesel yield is associated with catalysts characterised by more distinct pores, accounted for on the basis of XRD peaks below 15° 2θ (Figure 1) and associated with well-defined and increasing crystal sizes.
Crystal size proved to have a greater impact than the long-range crystallinity in defining the yield of biodiesel. Although the S-24 sample resulted in crystallite without a long-range order, that does not mean that the HS mineral phase was not formed (Figure 1). The high biodiesel yield obtained over the S-144 catalyst may be attributed to the higher Na/Al ratio exhibited by the sample, as well as the high Si/Al ratio thereof (Table 2). The latter serves as an indication of high degree of acidity or large amount of Bronsted acidic sites on the external surface of the S-144 catalyst sample [25]. Catalyst acidity was, therefore, in terms of Si/Al ratio, another critical factor in determining the yield of biodiesel.

The Quality of Biodiesel Produced

The quality of each biodiesel product obtained was characterised vis-à-vis the catalyst synthesis time and the corresponding properties. The property specifications of each biodiesel produced correlate to the EN1421 international standards (Table 4). The biodiesel obtained from the shorter synthesis time-based catalysts of S-12 and S-24 partially displayed the required standard specifications, with the latter adhering only in terms of viscosity (4.90 mm/s2), while both slightly exceeded the specifications in terms of other properties, such as acid value (0.56 and 0.60 mg KOH/g oil) and density (0.975 and 0.905 g/cm3). It can therefore be deduced that the almost entirely non-conforming biodiesel quality obtained over the S-12 and S-24 catalyst were as a result of the low shape-selective surface property and low diffusion constraint of these samples, while the effective biodiesel yield obtained by the S-24 catalyst was attributed to its relatively small crystal size.
As with the increase in the yield of biodiesel, a higher quality biodiesel product was associated with catalysts generated at higher synthesis times, starting from the 48-h synthesised catalyst (S-48) that yielded a slightly higher quality biodiesel as compared to the S-24 catalyst. Further, an increase in HS crystallinity, resulting from an increase in the catalyst synthesis time to ≥72 h, is associated with improved biodiesel properties such as acid value, density and enhanced ester content. Acid values of both S-72 and S-144 were below the maximum 0.5 KOH/g oil; comparably higher iodine values (56.86 and 50.17 g of I2 /100g oil respectively) are indicative of highly reactive biodiesel products. In contrast to the other obtained biodiesel properties, the biodiesel ester content obtained using the first four catalysts did not comply with the EN standard specifications, except when the S-144 catalyst was employed. The S-72 catalyst exhibited an ester content (62.64%) below the required standard specification and the S-144 sample yielded up to 97.5% ester content (Table 4). This observation suggests that increased HS crystallinity to an optimum of 85% enhanced the catalyst basic site strength (infused by the high sodium concentration or high Na/Al ratio exhibited in catalyst sample; see Table 2). Further, increased crystal size of 38.1 nm and defined crystal morphology of S-144 (Figure 2), promoted a relatively high diffusion constraints, large surface contact and longer contact period of reacting molecules over the catalyst. The high shape-selective catalytic surface environment also played a crucial role in the synthesis of an effective catalyst for a considerable biodiesel quality.

3. Materials and Methods

3.1. Materials

Coal fly ash (CFA) was obtained from a coal-fired power station located in the Mpumalanga region of South Africa. It was stored in an air-tight container and kept under dark conditions. Sodium hydroxide (NaOH) of 98% grade was purchased from Kimix chemicals, and sodium aluminate (50–56% Al2O3 and 40–45%) was obtained from from Sigma Aldrich. The in-house deionised water required in the synthesis of zeolite was obtained using laboratory water distillation equipment. Maggot oil, being the biodiesel feedstock of choice in this study, was obtained from the AgriProtein Company, located in Cape Town, South Africa.

3.2. Catalyst Preparation

A 5 M solution of NaOH was prepared using 50 mL of deionised water; this was mixed with 10 g of coal fly ash to achieve a 1:1.2 mass ratio of CFA to NaOH. The solution was then transferred into a 250 mL polypropylene bottle and subjected to ageing under stirring (800 rpm, 70 °C, and 1.5 h). The resultant aged gel solution was then transferred into a 100 mL, Teflon lined, stainless-steel autoclave, which was placed in an oven for hydrothermal crystallisation at 140 °C for 48 h. The initial conditions of the synthesis time were adopted from Musyoka’s [16] work. The resultant product was then cooled to room temperature, filtered and thoroughly washed with deionised water until a filtrate with a pH of about 10 was obtained. The product solid residue was dried in an oven at 70°C for 24 h. The dried sample was weighed, stored and a certain amount was characterised. Various batches were made using the above procedure which was repeated by varying the hydrothermal synthesis time (12, 24, 72 and 144 h). Product samples were named in accordance with the various synthesis times i.e., S-12, S-24, S-48, S-72 and S-144 respectively.

3.3. Catalyst Characterisation

All the produced coal fly ash-derived HS samples were characterised using X-Ray diffraction (XRD), Fourier Transform Infrared (FTIR) and Energy-dispersive spectroscopy (EDS) coupled with Scanning Electron Microscopy (SEM). The XRD analysis was conducted to determine the mineral phases and crystallinity of the samples, using a Bruker AXS, equipped with LynxEye detector and operating with Cu-Kα radiation (גKα1 = 1.5406 Å) at 40 kV and 40 mA. The raw XRD data of the characterised samples were afterwards interpreted with the aid of the Origin analysis software (version 8.5). The identification of the HS phase of interest was conducted using the standard and simulated XRD material data of sodalite, obtained from the database of the International Zeolite Association (IZA) [26]. The phase crystallinity of the catalyst samples was determined using the sum of the peak areas of the crystalline phase of HS over the sum of peak areas of that in the pattern of the reference sample (Equation (1)). The selection of the reference sample was based on the highest sum of the areas of HS peaks identified, of which the crystallinity was assigned as 100%.
%   Crystallinity = Sum   of   areas   of   the   crystalline   phase   of   interest   ( CPI ) Sum   of   the   area   of   CPI   in   the   reference   sample ×   100
The average crystal size of the produced samples was determined using the Scherrer equation depicted in Equation (2).
B ( 2 θ ) = K λ LCos θ
where L is the average crystallite size of interest in the sample in nm, B is the average peak Width or Full Width at Half maximum (FWHM) and θ is the diffraction angle in degree (converted to Radians).
The SEM analysis, coupled with EDS, was performed by mounting the powder of each sample on a stub coated with carbon conductive tape. Over this, the SEM-EDS (Data) mapping spectra were generated at three different regions of each sample using a high magnification ZeiSS Gemini Auriga instrument (equipped with a CDU-lad detector operating at 25 kV). The resultant data were used to determine the crystal morphology and elemental composition of each synthesised sample. The data of the EDS elemental composition were obtained as the average detected at each spectrum region and normalised without accounting for carbon content derived from coating. The FTIR characterisation, conducted using a Perkin Elmer 100 FT-IR, was used to determine the structural configuration of the samples. The latter was recorded to be in the range of between 450 and 2000 cm−1.

3.4. Biodiesel Production and Characterisation

The synthesised Na-form HS samples were then tested for transesterification of maggot oil. The reaction was conducted in a 250 mL, three-neck, round bottom flask equipped with a reflux condenser, over a laboratory hotplate. An amount of 20 g of oil was transferred into a 250 mL, two-neck, round bottom flask and preheated. To this the mixture of catalyst and methanol, equivalent to a catalyst weight of 1.5% to oil and a 15:1 mole ratio of methanol to oil, was added and reacted for transesterification at 60 °C for 1.5 h. The resultant product mixture containing the biodiesel (FAME) produced was centrifuged for layer and catalyst separation. The mixture was then transferred into the separation flask, in which it was washed with hot water until clear water was obtained. The washed biodiesel layer was then dried at 65 °C using anhydrous sodium sulphate. The layer was allowed to cool, weighed and stored prior to characterisation. The yield of biodiesel produced was determined using Equation (3).
B D   y i e l d   ( % ) = M a s s   o f   F A M E   o b t a i n e d M a s s   o f   o i l   f e e d s t o c k
The quality of both the maggot oil and biodiesel products obtained was determined and assessed according to the EN14214 standard method. The acid value was measured by the titrimetric method of potassium hydroxide solution [27]. The iodine value was determined according to Wij’s method [28]; the density and viscosity, both at 40 °C, were determined using an Anton Paar portable density meter (DMA) and a Discovery HR-1 hybrid (DHR) rheometer, respectively. Additionally, the refractive index (n) of the obtained samples was determined using a digital Refractometer (#PA203 Misco model). The fatty acid profile of the maggot oil feedstock and that of each biodiesel methyl ester produced (FAME) were characterised with a pre-calibrated GC-FID (HP88 GC model equipped with a polar capillary column).

4. Conclusions

This study showed that a pure phase hydroxy sodalite (HS) zeolite could be successfully synthesised from coal fly ash. The mineral phase of good crystallinity and high purity was represented by samples produced over longer hydrothermal synthesis time (≥48 h). The synthesised samples resulted in various degrees of crystallinity, which exhibited a direct correlation with the hydrothermal synthesis time. Various crystal morphologies evolved with an increase in the synthesis time, including hexagonal cubic crystals associated with high phase HS crystallinity. The high HS crystalline phases were also similar in structural characteristics and major elemental composition, including Si/Al ratio. The biodiesel yield and improved quality directly correlated with crystallinity and increased Na/Al ratio. The optimal HS phase with 100% crystallinity was obtained after a 72-h hydrothermal synthesis time. This catalyst sample also gave a high biodiesel yield of 84.10% and acceptable quality that met both the EN and ASTM specifications. This proves the potential of coal fly ash-derived hydroxy sodalite (HS) in biodiesel production and the economic viability of using a waste-derived catalyst and low-cost feedstock. Improved biodiesel yield and quality is envisaged upon further transesterification optimisation studies.

Author Contributions

Conceptualisation and validation, L.P., O.B.; methodology and software, J.M.S.; Formal analysis, O.O.; Writing—Original draft preparation, J.M.S., L.P. and O.O.; writing—review and editing, J.M.S., L.P. and O.O.; supervision, O.B., O.O.; project administration, J.M.S., O.B. and O.O.; Visualisation, L.P. and O.O.

Funding

The authors would like to acknowledge the Environmental NanoScience (ENS) group of the University of Western Cape for providing the required funding for sample analyses.

Acknowledgments

The authors would also like to acknowledge the Department of Chemical Engineering for additional facility to conduct the research at the Cape Peninsula University of Technology (CPUT); Agrifood Station at the Department of Food Technology (CPUT) for GC analysis; The Department of Physics at the University of Western Cape (UWC) and Ithemba Lab for the conduction of SEM and XRD analyses respectively.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. XRD patterns displaying the effect of synthesis time on HS formation.
Figure 1. XRD patterns displaying the effect of synthesis time on HS formation.
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Figure 2. SEM micrographs: (a) Arnot fly ash; (b) S-12 (HS catalyst sample synthesised at 12-h hydrothermal synthesis time); (c) S-24 (HS catalyst sample synthesised at 24-h hydrothermal synthesis time); (d) S-48 (48-h hydrothermal synthesis time HS catalyst); (e) S-72 (72-h); and (f) S-144 (144-h hydrothermal synthesis time HS catalyst).
Figure 2. SEM micrographs: (a) Arnot fly ash; (b) S-12 (HS catalyst sample synthesised at 12-h hydrothermal synthesis time); (c) S-24 (HS catalyst sample synthesised at 24-h hydrothermal synthesis time); (d) S-48 (48-h hydrothermal synthesis time HS catalyst); (e) S-72 (72-h); and (f) S-144 (144-h hydrothermal synthesis time HS catalyst).
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Figure 3. FTIR spectra of synthesised HS at various conditions of direct hydrothermal synthesis time: (a) CFA; (b) S-12; (c) S-24; (d) S-48; (e) S-72; and (f) S-144.
Figure 3. FTIR spectra of synthesised HS at various conditions of direct hydrothermal synthesis time: (a) CFA; (b) S-12; (c) S-24; (d) S-48; (e) S-72; and (f) S-144.
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Figure 4. Catalytic activity of synthesised samples as a function of synthesis time on FAME yield in biodiesel production from maggot oil under transesterification conditions [1.5-h reaction at 60 °C, 15:1 methanol-oil ratio and 1.5% catalyst w/w of oil].
Figure 4. Catalytic activity of synthesised samples as a function of synthesis time on FAME yield in biodiesel production from maggot oil under transesterification conditions [1.5-h reaction at 60 °C, 15:1 methanol-oil ratio and 1.5% catalyst w/w of oil].
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Table 1. Effect of hydrothermal synthesis time on phase crystallinity and crystal size of synthesised products at 140 °C.
Table 1. Effect of hydrothermal synthesis time on phase crystallinity and crystal size of synthesised products at 140 °C.
SampleSynthesis Time (Hour)HS Crystallinity (%) aCrystal Size (nm)
S-12121143.6
S-24241821.1
S-48489832.4
S-72 b7210031.9
S-1441448538.1
a Relative crystallinity. b Reference sample for crystallinity measurement.
Table 2. Effect of hydrothermal synthesis time on phase crystallinity and crystal size of synthesised products at 140 °C.
Table 2. Effect of hydrothermal synthesis time on phase crystallinity and crystal size of synthesised products at 140 °C.
SampleElement (Atomic, w/w%)
OAlSiNaMgKCaTiFePTotalSi/Al RatioNa/Al Ratio
CFA65.1511.2314.86-1.540.234.320.301.131.25100.01.32-
S-1258.6317.0817.493.040.580.371.300.900.62-100.01.020.18
S-2459.3516.5013.334.890.990.382.690.781.09-100.00.810.30
S-4845.0914.3219.514.620.65-3.570.931.33-100.01.361.02
S-7244.7713.9719.0715.240.96-3.780.791.43-100.01.371.09
S-14443.4713.7617.4220.67--2.161.231.29-100.01.271.50
Table 3. Physicochemical properties of maggot oil.
Table 3. Physicochemical properties of maggot oil.
Maggot Oil Properties
Acid value (mg KOH/g)7.2
Saponification value (mg KOH/g)176.43
Iodine value (g of I 2 /100 g)44.27
Density at 40 °C (g/mL)0.883
Kinematics viscosity at 40 °C (mm2/s)43.16
Fatty acid (wt.%)
C12:037.14
C14:07.1
C16:023.84
C16:13.16
C18:02.52
C18:117.81
C18:28.44
C18:3-
C20:0-
Table 4. Physicochemical properties of maggot oil.
Table 4. Physicochemical properties of maggot oil.
Biodiesel PropertiesObtained from Current Study for Respective SYNTHESISED CAtalystsB-STANDARD a
HS-12S-24S-48S-72S-144ENS b/ASTM c
Acid value (mg KOH/g)0.560.600.530.490.470.5–0.8 Max
Saponification value (mg KOH/g)-
-
-
-
148.59
-
Ester content d (% m/m)35.8342.4959.5662.6497.5096.5
Iodine value (g of I 2 /100 g)-
-
59.02
56.86
50.17
130
Density at 40 °C (g/mL)0.9750.9050.9310.8970.9070.86–0.90
Kinematics viscosity at 40 °C (mm2/s)6.18
4.90
5.73
5.70
5.73
3.5–5.0
1.9–6.0
Refractive index e1.4450
1.4443
1.4454
1.4450
1.4461
1.479
a Biodiesel Standard Specifications; b ENS14214 and c ASTMD675 (European and American). d Obtained from GC characterisation FAME data of respective biodiesel products. e Figures reported in four significant figures to enhance accuracy or minimise error of comparison.

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MDPI and ACS Style

Malonda Shabani, J.; Babajide, O.; Oyekola, O.; Petrik, L. Synthesis of Hydroxy Sodalite from Coal Fly Ash for Biodiesel Production from Waste-Derived Maggot Oil. Catalysts 2019, 9, 1052. https://doi.org/10.3390/catal9121052

AMA Style

Malonda Shabani J, Babajide O, Oyekola O, Petrik L. Synthesis of Hydroxy Sodalite from Coal Fly Ash for Biodiesel Production from Waste-Derived Maggot Oil. Catalysts. 2019; 9(12):1052. https://doi.org/10.3390/catal9121052

Chicago/Turabian Style

Malonda Shabani, Juvet, Omotola Babajide, Oluwaseun Oyekola, and Leslie Petrik. 2019. "Synthesis of Hydroxy Sodalite from Coal Fly Ash for Biodiesel Production from Waste-Derived Maggot Oil" Catalysts 9, no. 12: 1052. https://doi.org/10.3390/catal9121052

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