because hetero‐atomic functional groups containing such oxygen and nitrogen atoms were volatilized from the biomass structure [90]. The remaining elements in the biomass after the volatile compounds’ detachment rearranged themselves to form more aromatic structures, causing a reduction in the number of active sites.
2.5.2 Modified Biochar
To develop the physicochemical properties and the number of active species on biochar toward a higher activity and maximum catalytic performance, a large number of modification techniques have been investigated including metal modifications as well as chemical and physical treatments.
2.5.2.1 Tar‐reforming Processes
The production of syngas via biomass gasification has attracted a great deal of interest. However, this technology faces some challenges, the biggest one of which is excessive tar formation resulting in clogged up equipment. Consequently, the total cost of biomass‐derived syngas production is increased making it difficult to develop this process into industrial manufacturing. To overcome this drawback, tar removal technologies have been intensively researched with regard to their economic and environmental impacts. The catalytic thermochemical conversion using biochar catalysts has been reported as a capable technique for tar reforming, but currently still shows inferior performance compared to conventional metal‐supported catalysts. Particularly steam and CO2‐treated biochars are very powerful catalysts for tar reforming. The biochar prepared by pyrolysis from several biomass sources was activated with 15 vol% H2O mixed with argon or with CO2 at 800 °C for a short time. The treated biochar catalysts increased the catalytic activity in the steam or CO2 reforming of tar compared to a regular biochar. Treatment of the biochar resulted in an increased surface area and pore volume (both microporous and mesoporous), and high content of oxygenated functional groups [91, 92]. The CO2 generated more micropores in the biochar, whereas conversely, steam created more mesopores, which adds further importance for tar reforming. Even though micropores showed a greater initial tar conversion, these are rapidly deactivated due to coke deposition in the pores [4, 91, 93]. The steam‐activated biochar had more oxygenated functional groups in the aromatic C–O forms, which are more active sites for tar reforming, than those treated by CO2 [89, 92, 94]. Tar molecules were probably absorbed onto the unstable aromatic C–O structures on the biochar surface bringing about the transformation of tar into the gas products. When comparing the reforming gases, the treated biochar catalyzing the tar steam reforming was more effective than that in the CO2 reforming [95]. The steam fed during the reforming reaction could produce additional oxygenated functional groups and aromatic C–O structures [92], which resulted in a gradual increase in catalytic performance. Therefore, steam was a promising agent for boosting and preserving the catalytic activity of biochar in tar reforming.
As discussed previously, raw biochar had slower rates of tar elimination than metal‐supported catalysts. Doping an active metal such as Ni and Fe onto the biochar surface is another favored approach for the development of catalytic biochar [96]. Kastner et al. prepared biochar by pyrolysis of pine bark, which was then impregnated with Fe [97]. Compared to the regular biochar, the Fe‐modified biochar catalyst possessed a lower surface area and pore volume as the Fe particles could hinder and shrink the biochar pores. Although the physical properties of the Fe‐modified biochar catalyst were not remarkable, this catalyst showed that the tar decomposition rate was increased and the activation energy was decreased by 47%. The tar conversion was significantly altered by the metal loading and the tar decomposition increased with higher metal content on the biochar. At a decomposition temperature of 900 °C, the biochar modified with 13% Fe had a tar conversion of 100%. The addition of alkali along with the metal impregnation on biochar was developed in order to further enhance the catalytic activity. The raw biomass material was impregnated with potassium ferrate prior to carbonization at 900 °C for two hours to obtain a K–Fe bimetallic catalyst‐supported biochar [98]. The K2CO3 was formed as an active site of this catalyst and showed a superior catalytic activity in cracking of biomass pyrolysis tar at a relatively low reaction temperature (600–700 °C). The active metal sites and pore structure were still maintained after the reaction. This catalyst also showed a high stability as no significant change in tar conversion was observed after five cycles.
2.5.2.2 Biodiesel Production Processes
Biodiesel, a fuel derived from renewable sources such as vegetable oils and animal fats, has received much attention due to the continuous reduction in petroleum reserves and environmental issues. Biodiesel production via transesterification (Figure 2.5), also known as alcoholysis, is currently the most attractive approach, and can be divided into non‐catalytic, biocatalytic, and chemical catalytic processes. The non‐catalytic process or supercritical alcohol process is carried out in conditions above critical temperature and pressure of the reaction mixture determined from the critical properties of alcohols and triglycerides. This process requires a relatively high reaction temperature of 230–450 °C and high pressure of 19–60 MPa, as well as excess methanol (molar ratio of oil to methanol approximately 1 : 40). These requirements are a limitation to the non‐catalytic process for biodiesel production on an industrial scale [99]. A biocatalytic or enzymatic process produces biofuel with a low environmental impact and can be performed at mild temperature and pressure. Such processes are also not sensitive to the free fatty acid and water content in the feedstock [100, 101]. However, enzyme stability, enzyme reuse, and the high cost of enzyme immobilization are the major drawbacks of this process. In conventional biodiesel production, chemical catalysts (both acidic and basic) are usually used. Solid catalysts have been widely applied in biodiesel production owing to their ease of separation from products and excess reactants. A number of research studies have been conducted on biodiesel production using various types of acidic and basic solid catalysts. Most common is the solid base catalyst or alkali catalyst that can catalyze transesterification reaction in even milder reaction conditions and shorter reaction time than acidic solid catalysts. Calcium oxide (CaO) solid base catalyst can be derived from calcium carbonate‐rich materials such as horn shell and eggshell. With the basic catalyst produced from calcined eggshell, the biodiesel yield reached 97% in transesterification of waste cooking oil and methanol at the ratio of 1 : 6 [102]. Nevertheless, the preparation of a solid base catalyst from calcium carbonate‐rich feedstocks requires high temperatures of 800–900 °C. In addition, the free fatty acid and moisture contents in the oil feedstock should be considered for alkali catalysts. Water molecules in the feedstock can hydrolyze triglycerides into diglycerides and monoglycerides, which yield a greater amount of free fatty acids. The alkali catalyst is able to convert free fatty acids into soap via the saponification side‐reaction. The free fatty acid in the feedstock should be lower than 2% for transesterification.
Figure 2.5 Transesterification of triglyceride.
For feedstocks containing high free fatty acid content, the use of an acid solid catalyst is an alternative to produce biodiesel via esterification reaction (Figure 2.6) [103]. Several solid acids such as metal oxides (particularly ZrO2, TiO2, and SnO2), sulfonic acid‐modified materials, and heteropolyacids have been used in esterification [104–106]. Considering the economic aspect of the biodiesel production process, the price of raw materials and the catalyst are two major determinants of the overall biodiesel production cost [107]. Therefore, much attention has been paid to the utilization of low‐cost bio‐based carbonaceous solids in biodiesel production because of their inexpensive carbon sources, convenient preparation, and easily tunable physical and chemical properties [108]. Furthermore, covalent attachment of active groups such as SO3H, COOH, and phenolic OH groups