Catalytic Conversion of Palm Oil to Bio-Hydrogenated Diesel over Novel N-Doped Activated Carbon Supported Pt Nanoparticles

Bio-hydrogenated diesel (BHD), derived from vegetable oil via hydrotreating technology, is a promising alternative transportation fuel to replace nonsustainable petroleum diesel. In this work, a novel Pt-based catalyst supported on N-doped activated carbon prepared from polypyrrole as the nitrogen source (Pt/N-AC) was developed and applied in the palm oil deoxygenation process to produce BHD in a fixed bed reactor system. High conversion rates of triglycerides (conversion of TG > 90%) and high deoxygenation percentage (DeCOx% = 76% and HDO% = 7%) were obtained for the palm oil deoxygenation over Pt/N-AC catalyst at optimised reaction conditions: T = 300 ◦C, 30 bar of H2, and LHSV = 1.5 h−1. In addition to the excellent performance, the Pt/N-AC catalyst is highly stable in the deoxygenation reaction, as confirmed by the XRD and TEM analyses of the spent sample. The incorporation of N atoms in the carbon structure alters the electronic density of the catalyst, favouring the interaction with electrophilic groups such as carbonyls, and thus boosting the DeCOx route over the HDO pathway. Overall, this work showcases a promising route to produce added value bio-fuels from bio-compounds using advanced N-doped catalysts.


Introduction
The utilisation of renewable energy sources has been encouraged in view of economic and environmental considerations such as the energy crisis, rising crude oil price, air pollution and global warming, all of which stem from the dependence on fossil fuels. Biomass resources play the dominant role in the renewable energy portfolio. Statistically, the total primary energy supply from bio-resources constitutes approximately 70% of all the renewable energy sources in 2016 [1]. Biofuels are the leading renewable solution for the transport sector, in particular for heavy transport such as aviation and shipping. Biofuel production has increased 10 times from 16 billion litres in 2000 to 143 billion litres in 2017 [1]. Biofuel can be produced from organic residues and diverse bio-compounds such as triglycerides. The life cycle of biodiesel is shown in Figure 1. Natural triglycerides originating from vegetable oils and animal fats consist of a glycerol backbone with three fatty acid moieties [2].
They possess the potential to produce hydrocarbon fuels considering their simple structure and low degree of functionalization [3]. Typically, two main catalytic reactions could covert triglycerides into biofuel for diesel engines: (1) transesterification with methanol to produce fatty acid methyl esters (FAMEs); (2) catalytic deoxygenation process to produce bio-hydrogenated diesel (BHD), i.e., so-called green diesel. FAMEs, the first generation of biodiesels, is typically used as a component in diesel blending [4]. However, the deteriorated properties of FAMEs, such as limited compatibility with conventional diesel, low thermal and oxidation stability, and possible engine problems arising from the remaining of C=C and C=O bonds, limits their application in industry. In contrast, BHD derived from the deoxygenation of vegetable oil or animal fats presents better diesel properties such as high cetane numbers, zero oxygen, and high thermal and oxidation stability [5]. For instance, palm oil, which contains primarily C 16 and C 18 fatty acids, is a promising feedstock for the production of BHD through the catalytic deoxygenation process. The BHD derived from the deoxygenation of vegetable oil possesses a high cetane number, i.e., ranging from 85 to 99 [6], which is fully compatible with conventional diesel fuel. In the upgrading process, triglycerides are hydrogenated to produce saturated triglycerides [7], and then undergo hydrogenolysis reactions to produce fatty acids and propane gas [8]. Finally, the fatty acid could be subjected to a deoxygenation process to produce BHD. Three major reaction pathways typically occur in the deoxygenation of fatty acids, which include decarbonylation (DeCO), decarboxylation (DeCO 2 ) and hydrodeoxygenation (HDO) as pointed out in Figure 1 [9]. Specifically, these three processes consist of (1) DeCO, the elimination of oxygen in the form of CO; (2) DeCO 2 , the removal of oxygen in the form of CO 2 , and (3) HDO, the withdrawal of oxygen in the form of H 2 O. H 2 consumption for the deoxygenation of fatty acids follows the order DeCO 2 < DeCO < HDO [10]. N-alkanes produced from the HDO pathway maintain the same carbon number compared to the original fatty acid. In contrast, DeCO and DeCO 2 possess the advantages of consuming reduced or no hydrogen compared to HDO. Hence, DeCO x routes are attractive from an economic standpoint [11,12] considering the high cost of H 2 and the problems associated with hydrogen manipulation and transportation. The nature of the catalyst plays a primary role in the catalytic deoxygenation process. The earliest attempts to deoxygenate fatty acids date back to the year of 1936, which were conducted in a homogenous catalytic reaction system [13]. The heterogeneous catalysed deoxygenation (excluding pyrolysis) of vegetable-based feeds scarcely gained attention until the 21st century [14]. Heterogeneous metal catalysts are promising candidates for deoxygenation reactions considering their high reactivity at mild temperatures (<400 • C) and low H 2 pressure requirements. Nonnoble catalysts, such as Ni [10] and Co [3], and noble catalysts such as Pd [15], Pt [16] and Ru [14] have been demonstrated to be sensible choices for the deoxygenation of seed oil, fat oil or model compounds. Snare et al. did a comprehensive investigation about the deoxygenation of fatty acids and their esters over numerous metals (Pd, Pt, Ru, Mo, Ni, Rh, Ir and Os) supported on carbon or metal oxides [14]. Their results indicated that DeCO 2 is mostly favoured over Pd and Pt metal particles supported on carbon. In view of these results, investigations of fatty acid deoxygenation have been mostly focused on Pd and Pt-based catalysts in recent years [17][18][19][20][21]. Ni-based catalysts are also promising candidates for the deoxygenation of fatty acids, which could achieve comparable results with Pd and Pt catalysts by increasing their Ni content [22].
Irrespective of the active metal, the nature of the support is the key to ensure successful performance in the upgrading reaction. In this regard, nitrogen-doped carbons (NC) have received increased attention in recent years. It has been reported that the physical and chemical properties can be significantly improved by doping nitrogen into the carbon architecture, making NCs the leading materials in various applications such as supercapacitors, oxygen reduction catalysts and catalyst supports, etc. [23]. In particular, NC materials are widely used as catalyst supports, and perform well in the hydrodeoxygenation (HDO) of bio-phenolic compounds [24,25]. The introduction of N in the carbon structure modifies the electronic properties of the carbon matrix. More specifically, N alters the electronic density of the sp 2 carbon, thus facilitating H 2 activation on metal nano-particles (NPs) by lowering the dissociation energy [26]. It is reported that the nitrogen species in Ni/N-doped carbon black (NCB) greatly promote the reduction of metal oxides and promote the stability of metal particles at ambient atmosphere [27]. The good performance of NC-supported catalysts in the HDO of phenolics inspired us to explore their behaviour in the upgrading of other bio-resources, such as fatty acids. Indeed, very few reports dealing with the application of the NC-supported catalysts in the upgrading of fatty acids through catalytic deoxygenation process can be found in the literature, thus compelling us to investigate the matter [28].
In this study, a N-doped activated carbon supported Pt catalyst (Pt/N-AC) was synthesised and tested in a palm oil deoxygenation process to produce bio-hydrogenated diesel. The effect of the reaction temperature, pressure and space velocity was evaluated to explore the impact of key parameters aiming to optimise the reaction conditions for the upgrading process. The effect of nitrogen in the carbon structure on the catalytic performance of catalyst was illustrated, in which the performance of a reference Pt/AC was tested at optimised reaction condition as a contrast experiment. Our study could provide guidance for the selection of a catalyst and for the optimization of the reaction conditions for green diesel production from seed oil and fats.

Catalyst Preparation
For the preparation of the N-doped carbon (N-AC), polypyrrole was synthesised via oxidative polymerization in the presence of a commercial activated carbon (RGC-30). First, 2.4 g of activated carbon was dispersed in 200 mL of acetone with an ultrasonic treatment for 30 min. Then, 24 mmol of pyrrole (C 4 H 5 N) were dissolved in 200 mL of distilled water, and the solution was added to the AC dispersion. The mixture was stirred for 30 min, and then 48 mmol of ammonium peroxidisulphate ((NH 4 ) 2 S 2 O 8 ), previously dissolved in 200 mL of distilled water, was added dropwise. The resulting solution was stirred for 4 h at room temperature. The precipitated formed was filtered, washed with distilled water and dried at 80 • C for 24 h. The percentage of N in the synthesised N-AC was 3.3 at.%, which was derived from N1s core level XPS result. To obtain the final AC, the solid was pyrolysed for 4 h at 900 • C under flowing N 2 (50 mL/min) with a heating rate of 5 • C/min. The Pt/AC and Pt/N-AC catalysts were prepared by wet impregnation using chloroplatinic acid hexahydrate (H 2 PtCl 6 ·6H 2 O) as the Pt precursor. The carbon supports were immersed in aqueous solutions containing the appropriate amount of H 2 PtCl 6 to obtain 1 wt.% Pt loaded. The slurries were stirred for 24 h, and the solvent was gently removed under vacuum at 60 • C. Finally, the metal catalysts (Pt/AC and Pt/N-AC) were dried in an oven at 80 • C for 24 h. XRD data are included in the supporting info.

Catalyst Characterisation
Powder X-ray diffraction (XRD) patterns of the samples were collected on an X'Pert Pro PANalytical, using Cu Kα radiation (40 mA, 45 kV). The spectra were registered over a 2θ range between 10-90 • , with a step of 0.05 • and a time per step of 160 s.
Transmission Electron Microscopy (TEM) images were taken with a JEOL electron microscope (model JEM-2010) working at 200 kV. This was equipped with an INCA Energy TEM 100 analytical system and a SIS MegaView II camera. Samples for analysis were suspended in ethanol and placed on copper grids with a holey-carbon film support.

Catalytic Deoxygenation Testing
Catalytic deoxygenation experiments were carried out in an Autoclave Engineers BTRS high-temperature and high-pressure testing system, equipped with a high-pressure HPLC pump (Series I), followed by metering valves to control the flow rate of the liquid and gas feeding, respectively. A continuous flow, fixed-bed tubular stainless-steel reactor with an internal diameter of 0.7 cm, length of 30 cm and volume of 12 mL was used in the experiments. Prior to catalytic testing, a specific amount of catalyst (either 0.12, 0.09, 0.072, 0.06 g depending on the LHSV used) held in place using quartz wool was reduced in situ under a flow of 100 v/v % of H 2 (50 mL/min) under atmospheric pressure, at 400 • C, for 2 h. Next, the system was set to the desired reaction temperature under a flow of high purity N 2 (100 mL/min) and pressurised with H 2 to the desired pressure (controlled by a back pressure regulator). Liquid solutions of the feed i.e., 3 wt.% of palm oil dissolved in dodecane (solvent) were injected into the system at a rate of 0.1 mL/min, along with a flow of H 2 . The fatty acid compositions of the refined palm olein (wt.%) are listed in Table 1. Palmitic acid, oleic acid and linoleic acid occupy more than 95 wt.% of the fatty acid composition in palm oil. Liquid and gaseous products were passed through a liquid-gas separator which was placed downstream from the catalyst bed. Liquid products were manually collected for analysis using GC/MS. The effect of reaction temperature, H 2 pressure and liquid hourly space velocity (LHSV) were tested under constant H 2 /oil ratio, 1000 cm 3 /cm 3 in deoxygenation of palm oil over Pt/N-AC, and the optimised reaction conditions were obtained. To test the reproducibility of the experimental results, the experiments concerning the Pt/N-AC catalyst were repeated three times. From these experiments, 95% confidence intervals for the mean value were calculated. To explore the effect of N on the catalytic activity, a contrast test over Pt/AC was also conducted. Each test was performed for 6 h and the liquid products were analysed at 1 h intervals.

Product Analysis
The liquid samples were analysed on an Agilent 7890A/5975C Triple-Axis Detector diffusion pump Gas Chromatographer-Mass Spectrometer (GC-MS) (AGILENT, Santa Clara, CA, USA) equipped with an Agilent Multimode inlet. High injection and column temperatures were used to directly analyse triglyceride so as to avoid chemical derivatisation. A split ratio of 25:1 was held and a split flow of 50 mL/min was used. The temperature of the inlet was set at 300 • C for the duration of the analysis and the volume of the samples injected was 1 µL. The oven temperature program was initially set at 45 • C for 2 min; it was later increased by 4 • C/min to 325 • C, and then to 380 • C with a ramp of 10 • C/min. The maximum temperature was maintained for 12.5 min and the total run time was 90 min. An Agilent 30 m × 320 µm × 0.1 µm J&W DB5-HT capillary column (5% phenyl, 95% methylpolysiloxane) was employed to achieve chromatographic separation, operated under a constant flow rate mode of He (2 mL/min). The temperature of the ion source, the quadrupole and the MS interface for both instruments were 230, 150 and 330 • C, respectively. The GC/MSD ChemStation software (AGILENT, Santa Clara, CA, USA) was used to identify the species of products. A representative GC chromatograph identifying the product of liquid products is presented in Figure S1.
The conversion of triglycerides (TG), the yield of C 15 -C 18 products, the HDO percentage and also the decarbonylation and/or decarboxylation (DeCO x ) percentage were calculated using Equations (1)-(4), respectively. It should be noted that the relative activity of the DeCO and DeCO 2 could not be directly correlated with the amount of produced CO and CO 2 , considering that gas phase reactions such as methanation (i.e., CO + 3H 2 ↔ CH 4 + H 2 O and CO 2 + 4H 2 ↔ CH 4 + 2H 2 O) and the water-gas shift (WGS) reactions (i.e., CO + H 2 O ↔ CO 2 + H 2 ) could occur under the studied reaction condition (250-350 • C).

Deoxygenation of Palm Oil
In our deoxygenation reaction system, the deoxygenation of palm oil was performed under a H 2 atmosphere. Even though DeCO 2 of fatty acids does not need a supply of H 2 , the addition of H 2 could increase the rate of the deoxygenation reaction [29]. Moreover, it has been demonstrated that the aromatisation reaction can be inhibited to some extent under a H 2 atmosphere. The aromatisation reaction is undesirable, considering that aromatics could be the precursors to the formation of coke, which could lead to catalyst deactivation and reactor fouling [30].
Solvent type strongly affects the catalytic performance. A nonpolar organic solvent, dodecane, other than nonsolvent or water was used in our reaction system considering its multiple benefits. On one hand, the occurrence of coupling reactions between the intermediates in a solventless reaction system will decrease the selectivity of desired alkane products [31]. On the other hand, the flow rate of palm oil can be controlled well, especially in low feeding mode. Compared with using water as a solvent, the use of a hydrocarbon can omit the separation process of deoxygenated products from water. In addition, the presence of water may block the adsorption of the reactant on the active sites of the catalyst [32].

Effect of Temperature
Reaction temperature plays a fundamental role in the palm oil upgrading reaction. The effect of reaction temperature (250-350 • C) in the palm oil deoxygenation process using Pt/N-AC as a catalyst was investigated under the condition of 30 bar H 2 , LHSV = 1.5 h −1 and H 2 /oil ratio = 1000 cm 3 /cm 3 . At temperatures lower than 300 • C, the deoxygenation of triglycerides to n-alkanes is incomplete, with the conversion of TG being lower than 70%. Typically, reactants, intermediates and products will be co-existing in the collected liquid under these temperatures [3]. As demonstrated in Figure 2, the highest conversion of triglycerides, i.e., >90%, was achieved at 300 • C. However, the conversion decreased slightly with the increasing temperature (300-350 • C). It is speculated that a minor sintering of noble metal occurred when the temperature increased to 350 • C, resulting in a slight decrease in TG conversion.  Figure 2 also shows the total yield of C 8 -C 18 obtained from palm oil deoxygenation at different reaction temperatures. The palm oil used in our study was mainly composed of C 16 and C 18 (see Table 1). Thus, the dominant C 17 product is likely produced from C 18 though the DeCO x pathway. For temperatures lower than 300 • C, the total yield of C 8 -C 18 compounds was relatively low, considering the low conversion of the reactant. However, when the temperature is higher than 300 • C, the cracking of the carbon-Carbon chain was enhanced, resulting in a higher yield of light hydrocarbon compounds (C 8 -C 14 ). The details about the composition of light hydrocarbon products (C 8 -C 14 ) are shown in Table S1. The slight decrease of the total yield of n-alkanes when the temperature was higher than 300 • C could be attributed to the smooth depletion of TG conversion (Figure 2). This may also have been due to the formation of higher aromatic products, since in most cases, higher temperatures favour the production of larger aromatic compounds in the deoxygenation process [33]. As demonstrated in Equations (3) and (4), C 16 and C 18 products are produced from the HDO route while C 15 and C 17 are from the DeCO x pathway. The higher yield of C 16 and C 18 and lower yield of C 15 and C 17 indicated that higher temperatures favour the HDO but inhibit the DeCO x route (T > 300 • C).
To better understand the deoxygenation behaviour under different reaction temperatures, the contribution of different reaction routes, i.e., DeCO x and HDO, are also presented ( Figure 3). Overall, the DeCO x route dominated under all the studied temperatures. The results are consistent with previous studies showing that DeCO x was favoured over HDO for Pt-based catalysts in the deoxygenation of vegetable oil [3,34]. It is reported that the selectivity to DeCO x or HDO does not depend on the reaction temperature. Instead, the DeCO x or HDO pathway is determined by the nature of the catalyst [33]. At 300 • C, the DeCO x percentage occupies the highest proportion of deoxygenation capacity, whereas the HDO percentage is the lowest. This is advantageous from an economic perspective, given that DeCO x consumes much less H 2 than HDO. Overall, 300 • C is the optimal reaction temperature for deoxygenation of palm oil over Pt/N-AC catalyst considering the highest TG conversion and the total yield of C 8-18. At this temperature the DeCO x route is favoured over the HDO pathway.

Effect of H 2 Pressure
The effect of H 2 partial pressure in the deoxygenation of palm oil was investigated by varying H 2 pressure from 20 to 30 bar. As depicted in Figure 4, the raise of the H 2 pressure from 20 to 30 bar monotonously increased the TG conversion. Interestingly, as shown in Figure 5, higher H 2 pressure favours the DeCO x pathway but inhibits the HDO pathway. Accordingly, lower C 16 and C 18 but higher C 15 and C 17 was obtained under high H 2 pressure. The ratio of DeCO x /HDO increased from 3.3 to 13 when the H 2 pressure increased from 20 to 30 bar. This trend agrees with previous reports indicating that higher H 2 partial pressure suppresses the formation of aromatic hydrocarbons, hence increasing the selectivity of n-alkanes during deoxygenation process of vegetable oil model compounds [35]. Moreover, as shown in Figure 4, light hydrocarbons (C 8 -C 14 ) concentrations in the final product are reduced under high H 2 pressure, indicating that higher H 2 pressure could inhibit the cracking of C-C bonds in the deoxygenation process.

Effect of LHSV
Liquid hourly space velocity (LHSV) is an important parameter for regulating catalyst effectiveness. LHSV refers to the ratio of the feed flow rate to the volume of the packed catalyst [36]. A clear trend is observed in Figure 6 indicating that the deoxygenation of palm oil in terms of the TG conversion is favoured at low space velocities. This is actually expected, since the lower the space velocity, higher the reactants-catalyst contact time, favouring complete reaction cycles. The effect of LHSV on the product distribution is illustrated in Figure 6. At low LHSV the production of light hydrocarbon compounds (C 8 -C 14 ) is not favoured, whereas the production of C 15 and C 17 was greatly enhanced. At LHSV of 1.5 h −1 , DeCO x % possesses the highest value, i.e., around 75%, or nearly 10 times higher than that of HDO. When the LHSV increased from 2.0 to 3.0, the DeCO x % gradually decreased but the HDO% remained almost unchanged (Figure 7). This is an important partial conclusion suggesting that the HDO route is barely affected by the space velocity while there was a negative impact on the DeCO x route when the space velocity was increased.

Effect of Catalysts
In order to validate the positive impact of N as dopant, a reference Pt/AC catalyst was tested under the optimised reaction conditions: T = 300 • C, P(H 2 ) = 30 bar, LHSV = 1.5 h −1 and H 2 /oil ratio = 1000 cm 3 /cm 3 . The conversion of triglycerides (TG) and the yield of C 8 -C 18 n-alkanes in palm oil deoxygenation process over Pt/N-AC and Pt/AC are depicted in Figure 8. Clearly, the conversion of TG was improved over the NC-supported catalyst compared to the AC-supported catalyst. Specifically, the conversion of TG was more than 90% over Pt/N-AC catalyst, while the N-free catalyst barely reached 76% of overall conversion. Very interesting trends in terms of selectivity are also observed in Figure 8. For instance, the lower yield of light hydrocarbon compounds (C 8 -C 14 ) produced from Pt/N-AC catalytic system compared to that of the N-free catalyst indicates that the addition of N in the support suppresses the catalytic cracking of C-C bonds, resulting in higher selectivity towards long chain n-alkanes (C 15 -C 18 ). Another significant different between the compared catalysts is marked preference of Pt/N-AC to favour the DeCO x route compared to the Pt/AC catalyst. In fact, in both catalysts DeCO x is favoured over HDO under the studied reaction conditions but it is clear that the presence of N significantly favours DeCO x (Figure 9). This is a remarkable result from the process and catalysts design point of view since we can potentially control the selectivity by doping our carbon support with nitrogen. Figure 10 depicts the preferential interaction of carbonyl groups with N-doped carbons, which seems to control the catalytic upgrading of palm oil over Pt/N-AC catalyst. Indeed, the presence of nitrogen alters the electronic density as well as the acid/base properties of carbon affecting the overall reactivity. As reported previously, the higher activity of Pt/N-AC results from the positive role of N, which could help to stabilise metal particles and prevent the re-oxidation of metallic particles [27,37]. Also, nitrogen sites incorporated in the carbon network are envisaged as electron-rich sites where molecules can react. This also explains the higher selectivity for DeCO x when N is incorporated in the catalyst. Carbonyls are electrophilic groups which are prone to react with electronically rich species. Hence, we understand that N-sites in our catalyst act as preferential sites to anchor carbonyl groups of the palm oil feedstock boosting the DeCO x route over the HDO alternative. Irrespectively of the reaction pathways there is no doubt of the positive effect of N as dopant for the upgrading reaction.  A comparison of the catalytic performance of prepared Pt/AC and Pt/N-AC catalyst in this work with those of others is presented in Table 2. The conversion of TG (91%) in the present work is comparable to that obtained with other noble catalysts even though our experiments happened at lower temperature. Importantly, the yield of biodiesel production is much higher than those obtained over other noble catalysts. However, the conversion of TG in our reaction system is not as high as that reported over nonnoble catalysts, e.g., references [3,38]. However, it is worth emphasising that the DeCOx is the dominant reaction pathway in our reaction system, which is the preferable route from economic standpoint.

Characterisation of Catalysts
Further understanding of the behaviour observed for the N-doped catalyst is obtained by physiochemical characterisation of the sample. The textural properties of supports, AC and N-AC are shown in Table S2. The addition of N slightly decreased the surface area of carbon support. XPS of Pt 4f reveal that the addition of N shifts the binding energy of Pt indicating a modification of the Pt electronic environment as mentioned above ( Figure S2). This is expected to improve the stability of catalysts as reported elsewhere [39]. TEM and XRD of reduced and spent catalyst were analysed in this study. As shown in Figure 11, Pt/N-AC catalyst revealed the uniform dispersion of small Pt particles (average particle size of 2.2 nm) on the support. More importantly, the TEM image of spent Pt/N-AC remain almost unchanged compared to that of the fresh sample. No large agglomerates or obvious leaching were detected. Moreover, no difference can be found between the XRD pattern of reduced and spent Pt/N-AC catalysts ( Figure S3). Overall, the TEM and XRD analyses indicate that the Pt/N-AC system is a robust and stable catalyst showing great potential for bio-Compounds deoxygenation reactions.

Conclusions
This work showcases the application of advanced N-doped Pt-carbon catalysts for the conversion palm oil into added value drop-in biofuels. In this particular case, the upgrade consists of oxygen removal to boost the net energy value of the end product. Two routes for oxygen removal are observed, i.e., DeCO x and HDO, with the former being the preferential route in this study. The higher selectivity towards DeCO x products is due to the electronic modifications ascribed to N when it is incorporated in the carbon support network. This is a remarkable result from the process and catalysts design point of view, since we can potentially control not only the activity, but also the selectivity of the reaction by doping our carbon support with nitrogen.
The reaction conditions play a significant role in the process. For example, the overall conversion is favoured at higher pressures and low space velocities. As for the temperature, 300 • C seems to be an optimal choice. Again, the competition HDO/DeCO x was also affected by the reaction conditions. HDO was favoured at higher temperatures, while higher pressures favoured DeCO x . Interestingly, the space velocity barely affected the HDO route, but it did have a negative impact on the DeCO x pathway.
The N-doped catalyst is superior to a reference Pt/AC material and, very importantly, it is a very stable catalyst showing no signs of deactivation via sintering or carbon deposition during the reaction. Hence, this piece of work showcases an effective strategy to design highly active and stable catalysts for bio-compounds upgrades, and may inspire new opportunities in the area of low carbon, renewable fuel production. Attempts such as the effect of nitrogen source and amount of nitrogen in the catalyst's formula is worth exploration in the future to further improve the catalytic activity. Lessons learnt from the catalytic deoxygenation of refined vegetable oil to produce biodiesel could provide guidance for the application of inedible oil and waste cooking oil. Biodiesel production from inedible oil and waste cooking oil could alleviate the food vs. fuel debate, but there is still a long way to go.