1. 还原催化分馏 (RCF)
最有效的策略之一是木质纤维素生物质中天然木质素的直接氢解;也就是说,通过串联木质素解聚和稳定化,可以获得稳定的低分子量木质素油(酚单体、二聚体和小齐聚物)[
17 ]。这种方法现在称为还原催化分馏 (RCF) [
35 ],也称为催化上游生物精炼 (CUB) 或木质素早期催化转化 (ECCL),通过 H-转移反应使用 2-PrOH 作为 H -捐助者 [
36 ,
37 ]。在
表 2中,对实现高单体产率的选定反应系统进行了概括。
1.1. Role of the Catalyst Used
A general understanding of the RCF processes has been established through mechanistic studies, which can be summarized in three basic steps: lignin extraction, which entirely depends on the solvent; solvolytic depolymerization and catalytic hydrogenolysis; and stabilization, which is controlled by a heterogeneous, redox-active catalyst [
31]. Since the hydrogenolysis of C–O bonds is metal-dependent, the type and yield of products can be controlled by selecting an appropriate metal [
18]. Heterogeneous metals have been shown to catalyze lignin depolymerization efficiently, including Pt, Pd, Rh, and Ru, as well as Ni, which is abundant on Earth [
19,
38,
45,
49].
Sels and colleagues presented the RCF of birch with a Ru/C catalyst, in which the lignin fraction was degraded to a propyl-substituted phenol compound with a monomer yield of 52%. Cellulose retention reached 95%, while hemicellulose retention was only 47% among the carbohydrates, which were converted into C2–C6 sugar polyol products in the subsequent hydrolysis reaction [
35]. Furthermore, Pd/C and Ru/C catalysts were compared under identical conditions. As expected, the lignin product yields were similar for the two catalysts. However, the chemical structures of the products were quite different, and the Pd/C catalyst had a higher selectivity for lignin monomers rich in hydroxyl groups and a higher retention of carbohydrate residues [
45].
Luo et al. have shown that Pd/Zn synergistic catalysis is relevant to lignin conversion in terms of the cleavage of β-O-4 linkages and the follow-up hydrodeoxygenation [
50]. Furthermore, when different types of biomass feedstocks were treated with Zn/Pd/C, the native lignin was converted into two main products: dihydroeugenol and 2,6-dimethoxy-4-propylphenol, with lignin monomer yields ranging from 40% to 54% [
44]. Further mechanistic studies revealed a synergistic effect between Pd/C and Zn
II; it was proposed that the addition of Zn
II can activate and promote the removal of C
γ-OH from the β-O-4 bond [
51].
From the perspective of industrial applications, the development of low-cost and highly available catalysts is imperative. Song et al. presented a selective hydrogenolysis of natural lignin fractions from birch wood to dihydroeugenol, 2,6-dimethoxy-4-propylphenol, and a small amount of propenyl-substituted phenols using a Ni/C catalyst [
52]. Interestingly, the Fe-doped bimetallic catalyst showed stronger hydroxyl removal when compared to the Ni/C catalyst, and the monomer product distribution changed from PG-OH and PS-OH to PG and PS [
53]. Li et al. developed a new Ni-W
2C/AC bimetallic catalyst and found that there was a synergistic effect between the Ni and W
2C, which could significantly promote the formation of lignin-derived monomers. Carbohydrates were further converted into ethylene glycol and other diol products. This catalyst can be widely used in birch, poplar, pine, beech, and other raw materials [
54].
1.2. Influence of Solvents
In the process of the direct catalytic treatment of lignocellulosic biomass, solvent decomposition can cut the lignin–carbohydrate complex (LCC) between lignin and hemicellulose, realizing lignin stripping from the biomass substrates. Subsequently, the β-O-4 linkage bond in the lignin structure is broken under solvent decomposition. Soluble lignin fragments are then generated, which make further contact with the catalyst surface and complete the subsequent activation of the β-O-4 linkage bond into a single-molecule compound. Solvents play an important role in the delignification of biomass and lignin depolymerization, affecting the yield of aromatic monomers as well as the retention of carbohydrate pulps [
55,
56].
Sels et al. investigated the effects of different solvents on the RCF of birch wood. It was found that the higher the polarity of the solvent, the higher the degree of delignification. This was because highly polar solvents can better complete the dissolution of the wood fiber structure and make the solvents more accessible to lignin; among them, methanol and ethylene glycol showed the highest efficiencies for delignification. From the distribution of lignin degradation products in a Pd/C catalytic system, with the increase of solvent polarity, the monomers and dimers of degradation products increased, while the oligomer products significantly decreased, indicating that highly polar solvents can also accelerate the degradation of the lignin oligomer into monomers and dimers [
46]. A techno–economic analysis of the RCF process using different solvents was carried out by Beckham et al., who replaced the solvent in the methanol-case with ethylene glycol. Due to the lower vapor pressure of ethylene glycol, the overall reactor pressure was reduced substantially. Generally, lower pressure during RCF results in lower capital costs. On the other hand, ethylene glycol has a higher cost and higher energy consumption for solvent recovery than methanol. Overall, on the basis of supporting the sale of bioethanol at USD 2.50 per gallon of gasoline equivalent, the methanol case has a higher MSP–monomer fraction at USD 3.63 per kg, while the ethylene glycol case has a lower MSP–monomer fraction at USD 3.07 per kg [
14].
Sels and colleagues further investigated the effects of different alcohol/water-mixing solvent systems on the RCF, and their results showed that the addition of moderate amounts of water significantly enhanced the extraction efficiency of lignin. However, too much water resulted in a lower degree of delignification [
43]. Chen et al. also confirmed the positive effect of adding water on the yield of lignin monomers [
57]. It should be noted that, if pure water is used as the medium while the lignin fraction is efficiently separated and degraded, the carbohydrate fraction also undergoes hydrolysis reactions and almost all of the hemicellulose and about 20% of the cellulose are removed [
46]. Similar solvent-polarity effects can also be observed in other catalytic systems. When water replaced methanol as the solvent in the case of the Ru/C system, not only did the yield of phenol monomer decrease from 52% to 25%, but the carbohydrate fraction was also degraded into soluble polyols [
35]. A plausible explanation for this is the autoionization of water into H
+ acid ions under high temperature conditions, which can catalyze the hydrolysis of carbohydrate [
58]. In addition, the redeposition of dissolved lignin on the surface of lignocellulosic fibers should be considered when water is used as the solvent [
59]. Above all, a pure water system may not be suitable for the current direct catalytic reduction process of biomass feedstocks.
1.3. Flow-Through Reactors
The new strategy of reductive catalytic fractionation has been proposed to depolymerize and stabilize lignin by mixing metal catalysts and biomass; however, this usually results in the catalyst not being recovered. Thus, flow-through systems for lignin-first biorefinery were developed (
Figure 3). In 2017, two research teams introduced flow-through reactors for the RCF process, in which the biomass and catalyst were separated by filling into two different beds. The solvent was passed through the heated biomass bed to extract and partially depolymerize the lignin polymer. Then a liquid mixture of dissolved lignin fragments flowed through the catalyst bed for further depolymerization and stabilization of active intermediates [
48,
60].
Figure 3. The evolution of reactor configurations for reductive catalytic fractionation.
However, flow-through systems also have certain limitations. For example, they require harsh reaction conditions in order to realize efficient delignification and stabilization, which significantly increases reactor costs [
14]. Generally, the solvent consumption is high, because this design may increase the time taken by solvent-extracted lignin fragments to reach the catalyst bed, and partial lignin may undergo an irreversible condensation reaction, resulting in a decrease in the final phenolic-monomer yield and selectivity. Therefore, kinetic issues such as adequate mass transfer between active lignin fragments and the catalyst need to be considered [
48,
60,
61,
62].
Beckham and colleagues demonstrated that the lignin oil obtained from the flow-through system could be stored for a long time without compromising subsequent hydrogenolysis activity, but the unusually high ratio of solvent to biomass made it difficult to implement on an industrial scale [
63]. In 2021, the team found that solvent usage exhibits a significant effect on the GWP; with the methanol solvent loading reducing from a 9 L/dry kg biomass to a 4 L/dry kg biomass, the GWP reduces from 0.079 kg CO
2-eq/kg to a −1.078 kg CO
2-eq/kg lignin fraction [
14]. On this basis, a multiple flow-reduction catalytic fractionation strategy has been proposed, which successfully reduced the solvent–biomass ratio to 1.9 L/kg with no significant decline of lignin oil quality found in the case of catalyst overload. This strategy greatly reduces the energy demand and operation cost of solvent recovery, which has a good development prospect [
64].
2. Stabilization Strategies
Given that the effective extraction of lignin with a high purity and less-condensed structure from lignocellulosic biomass is crucial for lignin valorization, various biomass-fractionation technologies have been developed [
65]. Extraction with supercritical fluid using CO
2 in a supercritical condition is generally applied, which can enhance the accessibility of biomass and reduce the pretreatment temperature [
66]. Moreover, organosolv pretreatment is considered one of the most promising methods for biomass fractionation. The organic media can realize a higher lignin extraction efficiency thanks to its higher lignin solubility when compared to water [
67]. In
Table 3, selected extraction systems which achieve high-lignin isolated yields are generalized.
Table 3. Solvent- or co-solvent-assisted lignin extraction from biomass feedstock.
The theoretical maximum yield of lignin depolymerization to monomers is approximately the square of the cleavable interunit ether bond (β-O-4) content [
6]. Therefore, the retention of the reactive β-O-4 bond is one of the means to realize lignin valorization [
21]. Alcohols can act as external nucleophiles to capture benzyl carbocation intermediates and form ether at the α-position of the β-O-4 bond, which further inhibits the condensation reaction [
22,
32]. Lancefield et al. found that most of the β-O-4 bonds were retained in bioethanol- and biobutanol-extracted lignin [
74]. Zhu et al. found that higher yields of monomers were obtained by the depolymerization of benzyl alcohol after microwave-assisted methylation, which meant that etherification improved the reactivity of the β-O-4 bond [
75]. Deuss and colleagues reported the semi-continuous extraction of high β-O-4 content lignin with butanol in a flow-through system, thereby reducing the difficulty of further catalytic depolymerization [
72]. However, when compared to reductive catalytic fractionation, the alcohol–etherification approach usually produces a lower yield of phenolic monomers owing to inefficient lignin extraction and incomplete intermediate capture [
32].
In 2015, Barta and colleagues proposed the addition of ethylene glycol as a functional group protector to produce a stable G/S-C2-glycol acetal (1,3-dioxolane) structure through its combination with the acidolysis reaction intermediate, thus improving the yield of aromatic monomers [
23,
76]. On this basis, De Santi et al. used the green solvent dimethyl carbonate (DMC) to replace 1, 4-dioxane and toluene; meanwhile, sulfuric acid was used to replace the expensive iron (III) trifluoromethanesulfonate (Fe(OTf)
3). The monomer yield reached 9 wt% when pine was used as raw material [
77].
In 2016, Luterbacher and colleagues reported the addition of formaldehyde to organic solvent processing to avoid repolymerization during lignin extraction. This method takes advantage of the functional group protection of formaldehyde: formaldehyde reacts with α-OH and γ-OH on the side-chain of lignin to form a stable 1, 3-dioxane structure through acylation, which inhibits the formation of benzyl carbocation. At the same time, the electron-rich positions on the aromatic ring (usually the positions ortho or para to methoxyl groups) are easily replaced with protonated-formaldehyde electrophilic aromatics to form a hydroxyl methyl group, which further blocks the polycondensation reaction site [
24]. Recently, the team demonstrated that the extracted lignin was able to achieve steady-state, continuous depolymerization with a Ni/C catalyst in a flow-through system, in which the yield of 45% monophenol was achieved and maintained for 125 h [
78].
2018 年,Abu-Omar 及其同事使用甲醇和稀硫酸与少量甲醛的混合溶剂来提取木质素。超过 68% 的杨树木质素被 Ni/C 催化剂提取和解聚,产生三种主要的酚类单体:异丁香酚、4-丙烯基丁香酚和愈创木酚,总产率为 63% [
70 ]。这种提取方法也适用于核桃壳生物质。与乙醇相比,甲醇作为一种更强的亲核试剂,在保护碳正离子中间体方面更有效[
71 ]。
综上所述,利用醇类或醛类稳定木质素中间体的方法与既定的有机溶剂制浆方法基本兼容。与RCF工艺相比,其最大的优势是可以将生物质分级分离与后续的解聚步骤分开,使两个步骤可以独立优化,解聚更加灵活。因此,只需调整溶剂和反应条件[
32 ]。
This entry is adapted from the peer-reviewed paper 10.3390/en16010125