Revealing Structural Differences between Alkaline and Kraft Lignins

Publication Date (Web): March 19, 2019. Copyright © 2019 American Chemical Society. *E-mail: [email protected]. Tel.: +86 2-87113953. Cite this:Ind...
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Revealing Structural Differences between Alkaline and Kraft Lignins by HSQC NMR Chengke Zhao, Jingtao Huang, Linjie Yang, Fengxia Yue, and Fachuang Lu Ind. Eng. Chem. Res., Just Accepted Manuscript • DOI: 10.1021/acs.iecr.9b00499 • Publication Date (Web): 19 Mar 2019 Downloaded from http://pubs.acs.org on March 25, 2019

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Revealing Structural Differences between Alkaline and Kraft Lignins by HSQC

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NMR

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Chengke Zhao,† Jingtao Huang,† Linjie Yang† Fengxia Yue† and Fachuang Lu✲,†, ‡

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Guangzhou, 510640, China

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✲ Corresponding

State Key Laboratory of Pulp and Paper Engineering, South China University of Technology,

Guangdong Engineering Research Center for Green Fine Chemicals, Guangzhou 510640, China. author: Fachuang Lu, E-mail: [email protected], Tel: +86 2-87113953

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ABSTRACT:

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Technical lignins, mostly generated as by-products from pulping industry, are highly abundant

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aromatic sources. However, they are underutilized due to their complexity, as well as the structural

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alteration during chemical pulping processes. In-depth elucidation of technical lignins is becoming

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essential for their valorization in view of lacking understanding of technical lignins structures. In

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this work, Alkaline and Kraft lignins were prepared and comparatively characterized by 2D HSQC

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NMR. By applying authenticated reference compounds, the phenylglycerol structures, characteristic

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of the cleavage of non-phenolic β-aryl ether by Soda pulping, in the alkaline lignin were identified

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and quantified by 2D HSQC NMR. Phenylglycerol structures in alkaline lignin were estimated to

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be 8% - 14%, which was much higher than that in Kraft lignin. This finding was supported by the

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results from model studies, i.e., the yield of phenylglycerol product was 40% that obtained from

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soda pulping treatment of non-phenolic β-aryl ether compound while the yield of that from kraft

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treatment was lower than 5%. In addition, styryl ether structures from phenolic β-aryl ethers of

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alkaline lignin were also revealed by 2D NMR. These new findings will benefit to mechanistic

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understanding of lignin reactions and structural elucidation of technical lignins, which will provide

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useful information (or new insights) for the development of lignin valorization strategies.

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KEYWORDS: Alkaline lignin; Kraft lignin; Structural elucidation; 2D HSQC; β-O-4 linkage; Aryl

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glycerol

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1. INTRODUCTION

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Lignins are abundant biopolymers present in plants accounting for approximately 30% of non-

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fossil organic carbon on the earth.1-2 Owing to their high carbon content and aromatic structural

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units, lignins have great potential to be used for producing chemicals, biofuels and materials.3-7

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Lignin is made mainly from three monolignols: p-coumaryl, coniferyl and sinapyl alcohols, which

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make up lignin polymer through end-wise radical coupling reactions forming aryl ether and carbon-

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carbon (C-C) bonds between units. In principle, β-aryl ether linkage (β-O-4) is the most abundant

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interunit linkage type, which constitutes of over 50% of all interunit linkages in lignin.1-2

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Technical lignins are primarily obtained from lignocellulosic biomass pulping processes for

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cellulosic pulps. During a pulping process, complicated reactions happen to lignin, which lead to

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the cleavage of large number of aryl ether bonds and generation of many uncertain condensed

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structures bearing stable C-C bonds.8-10 Such reactions cause severe structural alterations of the

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resultant technical lignins. That makes structural analysis and the valorization of technical lignins

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very challenging.4, 11-12 In paper industries, a large amount of technical lignins can be produced,

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while they are underutilized and usually used as fuel to burn or even discharged with other

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components in spent liquors.13-14

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Nowadays, NMR spectroscopy is becoming more and more useful tool for the structural

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elucidation of lignins. The application of advanced heteronuclear 2D NMR in the lignin analysis

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has greatly improved the structural understanding of these materials. Many efforts have been

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focused on the characterization of various technical lignins by HSQC (heteronuclear single-quantum

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coherence) NMR technology,15-21 and have provided many insights into their structural features,

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which not only are significant for the understanding of lignin fundamental reaction during 3

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processing, but also helpful for developing efficient process for lignin valorization. Recently, with

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the aids of advanced lignin model compounds, the structure of some technical lignins, both in terms

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of interunit linkages and functional groups, has been revealed. Structures with styryl/enol ether,

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stilbene, epiresinol, diarylmethane, and end-groups (arylglycerol, aryl acetic acid, aryl propanol, β-

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hydroxy acid) have been identified by 2D HSQC in kraft lignins.10, 12, 22-25 However, structures of

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kraft lignins were various,10, 26 and highly dependent on pulping processes, conditions, and even

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their separation methods. Some structures being minor or ignored in one case could become

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significant in another one. For instances, the aryl glycerol/phenyl glycerol structure, a major product

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from cleavage of β-O-4 compound, has chronically been suggested be produced under alkaline

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pulping conditions.16, 27-29 However, it has not been reported in technical lignins until recently, in

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which kraft lignins were found to contain small quantity of arylglycerol structures. 12

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Recently, an alkaline/soda lignin (AL) produced from eucalyptus soda pulping process with

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addition of a deresinator (a surfactant) drawn our attention because of three strong correlation

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signals at: δC/δH 74.4/4.43, 75.8/3.56 and 63.4/3.21-3.85 (partial spectrum is shown in Figure 1A,

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full spectrum is shown in Figure S1) in 2D HSQC NMR of the AL. Alkaline pulping without adding

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the deresinator also produced lignin with similar NMR characteristics. Although these signals were

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very close and potential to be the C-H correlations of phenylglycerol’s side chain, they were

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suspicious since such strong signals have not been reported in many technical lignins. This

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observation promoted us to revisit the β-O-4 lignin model reactions in such alkaline treatments,

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performing careful assignment of these signals and structural comparison of ALs with kraft lignins

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(KLs) aimed to identify or confirm the produced structures.

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Herein, we report the isolation and 2D HSQC comparative characterization of the ALs and 4

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KLs from spruce and eucalyptus wood, with focus on quantitation of phenylglycerol and styryl

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structures produced from cleavages of β-O-4 linkages in lignin models and lignins under Soda or

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Kraft pulping conditions. Our findjngs will provide with a deeper understanding on the features of

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technical lignins (ALs and KLs) for better lignin utilizations.

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2. EXPERIMENTAL

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2.1. Materials

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Spruce (softwood) and eucalyptus (hardwood) wood chips with about 3 cm length and 2 cm

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width, obtained from local pulping mills, were used as pulping feedstocks. The wood chips were

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thoroughly washed with water and dried at 80 °C for 12 h in oven. Lignin model compound, 4-

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benzyloxy-3-methoxyphenyl glycerol-β-aryl ether (seen in Scheme 1), were synthesized according

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to published methods.30 The method for synthetizing styryl ether compounds (Z/E-isomers) was

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described in supplementary materials. Two types of phenyl glycerol compounds, 3-methoxy 4-

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hydroxyl phenylglycerol and 3,5-dimethoxy-4-hydroxyl phenylglycerol were synthesized as

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previous reported.31 The corresponding benzylated and acetylated products were synthesized, and

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the structures were confirmed by NMR (Figure S4 - S11). Other chemicals used in this study were

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purchased from Macklin Biochemical Co., Ltd. (Shanghai, China).

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2.2 Quantitative analysis of products from reaction of model compounds

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The reactions of lignin model compounds under pulping conditions were performed in a 20-

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mL hydrothermal reactor.

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solution (8 mL) or 1M NaOH and 0.25 M Na2S solution (8 mL) for alkaline treatment or Kraft

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treatment, respectively. The hydrothermal reactor was put in an oven and the temperature was kept

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at 170 °C for 2 h. Then, the reactor was cooled down with tap water. The pH value of the reaction

20 mg of non-phenolic dimeric compound were added into a 1 M NaOH

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liquid was adjusted to below 3 by adding 3% HCl. The acidic turbid liquid was extracted with

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CH2Cl2 (4×10 mL). The combined organic layers was washed with saturated NaCl and dried with

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anhydrous MgSO4. After filtration, the filtrate was collected into a flask and evaporated under

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reduced pressure.

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The reaction products were analyzed and quantified by GC/MS after trimethylsilyl

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derivatization by using of standard compounds. The products in flask were dissolved into 4 mL

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CH2Cl2 from which 1 mL of solution was transferred into a GC vial. After pyridine (150 μL) and

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N, O-bis trimethylsilyl trifluoroacetamide (BSTFA, 98%, 150 μL) were added into the vial, the

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mixture was heated to 60 °C and kept for 40 min. The TMS-derivatized products were analyzed by

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GCMS-TQ-instrument (Shimadzu GCMS-TQ8040 triple quadrupole GC/MS/MS) equipped with a

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SH-Rxi-5Sil MS column (Shimadzu, 30 m × 0.25 mm × 0.25 μm). The solutions with different

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concentration of reference compounds (phenylglycerols, styryl ethers and other compounds) were

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prepared and analyzed by GC/MS under the same conditions. The content of reaction products was

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determined by plotting the calibration curve (peak area vs. reference compound concentration). The

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product yield was calculated based on the amount of reacted dimeric compound, as follows:

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Yield % 

n product n0  n

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Where n product is the molar amount of product, n0 and n are the molar amount of the initial β-O-4

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dimer used and the remained β-O-4 dimer, respectively.

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2.3 Cellulolytic enzyme lignin preparation

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The cellulolytic enzyme lignin (CEL) was prepared according to the method described in the

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literature.32 Briefly, the wood chips were smashed to obtain the meal sample between 30 - 80 mesh,

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and then extracted with 80% ethanol. The extractive-free sample (3 g) was subjected to ball-milling

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by using a PM 100 mill (Retsch, Germany). The ball-milled sample (8 g) was incubated at 40 °C,

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in a 20 mM NaOAc buffer (100 mL, pH 4.8) containing 300 mg Celluclast 1.5 L (a cellulase with

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enzymatic activity value of 700 EGU/g, Novozymes) and 400 mg Viscozyme L (a cell wall

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degrading enzyme complex with enzymatic activity value of 100 FBG/g, Novozymes) for 48 h (2

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times). Then, the suspension was centrifuged, and the solid residue was freeze-dried, extracted with

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96% dioxane (100 mL, 12 h, 2 times). After centrifugation, the supernatant was collected and

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concentrated to ~3 mL, then transferred into 45 mL cold water in a centrifuge tube. The precipitated

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solid products (CEL) were collected by centrifugation. The CEL was finally obtained after freeze-

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drying. The CEL yields for spruce and eucalyptus were 38% and 44% respectively, based on the

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klason lignin of these two kinds of wood materials.

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2.4 Alkaline lignin and Kraft lignin preparations

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The alkaline and Kraft pulping processes of wood feedstocks were conducted in a 1 L digester.

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The dosage of chemicals and the liquor ratio are listed in Table S1. More drastic conditions are

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generally used for spruce pulping process than those used for eucalyptus due to more condensed

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lignins of spruce.33 After pulping, the pulp yields from alkaline and kraft processes were all over

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50%, and over 90% lignin was dissolved in the pulping black liquor --- the residual lignin content

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in pulp was less than 4% for eucalyptus, and about 5% for spruce. The lignin was precipitated out

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by blowing CO2 into the stirred spent liquor (100 mL) to lower its pH to 8.5. The crude lignin (70%

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- 80%, based on the lignin removed from feedstocks) was collected after centrifugation and air-

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drying. Then the crude lignin was washed with deionized water (2 × 100 mL, pH 5) to remove

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some salts and saccharides. After centrifugation and freeze-drying, small molecular fraction was 7

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removed by extraction with CH2Cl2 (3×50 mL). Finally, the purified lignins (28 - 46% yield based

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on the lignin removed from feedstocks, Table S2) were obtained.

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2.5 Acetylated derivatization of lignins

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Lignin sample (200 mg) was dissolved in pyridine/acetic anhydride (1:1, v/v) solution. The

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reaction mixture was kept at room temperature for 12 h. The product solution was dried under

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reduced pressure at 45 ° C, co-evaporating with additional ethanol several times to remove the

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pyridine and acetic acid.

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2.6 2D NMR HSQC experiments

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NMR spectra were recorded on a Bruker AVANCE Ⅲ HD 600 MHz spectrometer. Lignin

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model compound (~10 mg) or lignin preparation (80 mg) was dissolved in 0.5 mL DMSO-d6 in a

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NMR tube, respectively. The Bruker program of “hsqcedetgpsisp 2.3” was selected for HSQC

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(heteronuclear single quantum coherence) experiments. HSQC experiments for the lignins were

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performed using the following parameters: acquired from 10 to 0 ppm in F2 (1H) with 2048 data

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points and a 1s recycle delay, 160 to 0 ppm in F1 (13C) with 256 increments of 64 scans. The total

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acquisition time for a sample was 5 h. The experiments for the model compounds or the reaction

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products of β-O-4 dimer were acquired in F1 (13C) with 256 increments of 8 scans, and the total

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acquisition time was about 37 min. The central DMSO solvent peak δppm (39.5, 2.49) was used for

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calibration of correlation peaks. Volume integration of contours in HSQC spectrum used Bruker’s

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Topspin 4.0.3 software.

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3. RESULTS AND DISCUSSION

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3.1 Identification of phenylglycerol structures in ALs by 2D HSQC 8

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The 2D HSQC spectrum of AL from eucalyptus wood showed three strong signals (δC/δH

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74.4/4.43, 75.8/3.56 and 63.4/3.21-3.85, Figure 1A) close to those of C-H correlations from

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sidechain of phenylglycerol structures based on the reported data.34 In order to verify such structures,

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two types of model compounds, 3-methoxy 4-benzyloxy aryl glycerol (G-gly) and 3,5-dimethoxy-

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4-benzyloxy aryl glycerol (S-gly), representing the potential guaiacylglycerol and syringylglycerol

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structures in alkaline lignins, were synthesized and characterized with 2D HSQC NMR. The C-H

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correlations of G/S-glycerol sidechains are summarized in Table 1. When comparing HSQC spectra

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of the authenticated phenylglycerol compounds G-gly and S-gly with that of AL (Figure 1A, B and

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C), it was obviously that the three broad signals at δC/δH 73.2-75.2/4.34-4.54, 74.7-76.9/3.43-3.65

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and 61.2-65.6/3.19-3.89 for AL match well with those correlations in spectra of G-gly and S-gly

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corresponding to Cα-Hα, Cβ-Hβ and Cγ-Hγ correlations (Figure 1B and 1C). The broader

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correlations found in the spectrum of AL than those obtained from model compounds (single isomer)

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could be contributed to the isomeric/diverse structures and polymeric features of AL. The structures

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were further verified by comparing the HSQC spectra of acetylated reference compounds and AL

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(Figure 1D). The correlations associated with glycerol sidechain changed to δC/δH 72.6/5.86,

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71.3/5.34 and 61.5/3.91- 4.13 after acetylation. The acetylated AL also showed strong correlation

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signals at this area, and the signals of the lignin polymer completely overlapped with peaks of

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compounds. Both assignments on the native and acetylated ALs provided strong evidences that the

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three strong signals in the AL belong to phenylglycerol sidechain moiety.

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Table 1. 13C and 1H chemical shifts (ppm) of side chains of 3-methoxy 4-benzyloxy aryl glycerol (G-gly) and 3,5-dimethoxy-4-benzyloxy aryl glycerol (S-gly) in DMSO-d6.

Model

G-gly

S-gly

α

72.4/4.45

73.0/4.47 9

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β γ

75.4/3.47 62.3/3.16 and 3.34

75.6/3.49 62.5/3.19 and 3.36

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Figure 1. Partial 2D HSQC NMR spectra of non-acetylated/acetylated eucalyptus alkaline lignin (AL) and phenylglycerol compounds for peak assignment. The unknown peaks in (A) eucalyptus AL were compared with the peaks from (B) G-gly and (C) S-gly. The phenylglycerol structure in AL was also confirmed by matching the peaks from acetylated compounds and acetylated AL (D).

3.2 Structural comparison between ALs and KLs revealed by 2D HSQC

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As shown in Figure 1A, the content of phenylglycerol structure revealed by 2D HSQC NMR

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in the eucalyptus AL was very significant (~ 10%). However, it is interesting that such structures or

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the signals were ignored or not recognized in many technical lignins before.10, 18, 20-21, 23 Therefore

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efforts were made here to quantitatively estimate these structures in ALs and KLs.

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In native lignin, the non-phenolic β-O-4 unit is the dominant linkages, accounting for over 50-

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60% of all linkages. Pulping process under alkaline conditions could generate phenolic units by

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cleaving β-O-4 ether bonds. Although the reaction pathways of phenolic/non-phenolic β-O-4 10

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models in alkaline treatment has been reported, the quantitative comparison of their products under

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alkaline (NaOH-only) and kraft (NaOH + Na2S) conditions was lacking.6, 9-10, 25 In current study,

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quantitation of products from phenolic β-O-4 models (dimers) suggested that alkaline process

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resulted in higher yield of styryl ether products (39%, including 15% Z-isomer and 24% E-isomer),

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than the kraft process did. Therefore, sulfides apparently facilitated the cleavage of the β-aryl ether

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linkage, leading to higher guaiacol yield (from 21% to. 33%) and decreased the yield of styryl ether

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(from 38% to 23%) under the kraft conditions (Scheme 1). These results can be explained by the

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nucleophilic attack of HS- to the quinone methide intermediate at α-position forming a sulfite that

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facilitates the cleavage of the β-aryl ether via neighboring assistance mechanism,7, 35 reducing the

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formation of styryl ether. As for the non-phenolic dimer concerned, the yields of phenylglycerol

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obtained in soda pulping were different from that obtained in kraft pulping, being 40% (based on

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the reacted starting dimer), much higher than that (< 5%) from kraft pulping (Scheme 1). This

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implied that the strong nucleophilic HS-/S2- in kraft process accelerates cleavage of -ether leading

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to formation of mercaptide or polysulfide species (Sx2-),7, 35 instead the production of phenylglycerol

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structure that was major products in Soda pulping.

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Scheme 1. Quantitative analysis of the products from β-O-4 compounds after alkaline and kraft

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quantity of reacted dimer (Figure S14 and S15). Less syringyl monomer was detected compared to the

formation of phenylpropyl derivatives after alkaline treatment, potentially due to some condensation reactions involving syringyl monomers.

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Based on the above discussion about the model studies, more detailed structural features of

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ALs and KLs from both eucalyptus and spruce were then comparatively analyzed by 2D HSQC

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NMR. Carbon dioxide (CO2) was used to adjust the pH (to 8.5) of pulping liquors to precipitate and

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recover the alkaline and kraft lignins. It is a “green” and low-cost process (called Ligninboost

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process, commercialized in Europe) compared to the use of inorganic acids, and has been tested to

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be preeminent in pulp/paper mills from an engineering and economic point of view.36 Although a

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further reduction of pH value of pulping liquor by using acids can recover more lignin components,

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the portion recovered under acidic condition has very low molecular weight, and contains more

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carbohydrates.37 This portion was not considered in our work. The cellulolytic enzymatic lignins,

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CELs, were used as references. The aliphatic oxygenated and aromatic/unsaturated regions (δC/δH

treatments. The yields of products were determined by external standard method based on the mole

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45-135/2.5-8.0 ppm) were mainly concerned. The relative abundance of interunit linkages or

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functional groups was estimated by integrating the corresponding correlated contours in their HSQC

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spectra (the aromatic G2 (and S2,6) signals were used as lignin reference).

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As shown in Figure 2, the dominant interunit linkage in CELs was β-aryl ether linkage (β-O-

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4, A, 55-60%), followed by phenylcoumaran and resinol. Phenylglycerol structures were not

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observed in the HSQC spectra of CELs (Figure 2), although it could be produced by ball-milling

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during lignin isolation process.38 Pulping process with alkaline media promotes biomass

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delignification by cleaving aryl ether bonds and solubilizing lignin.39-40 In the spectrum of ALs, a

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small amount of β-O-4 linkage (6.0%) and phenylcoumaran structure (5.2%) were observed in the

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spruce AL whereas no β-O-4 and phenylcoumaran can be identified in the eucalyptus AL. This

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observation agrees that the β-aryl ether linkage of G units was more stable than that between G and

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S units or S and S units.41-42 The resinol (β-β) structures with the stubborn C-C linkage was

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substantially reserved during alkaline and kraft treatments. The signal at δC/δH 53.0/3.73 belongs

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to the Cα-Hα correlation of α-5 linkage (E), arisen from condensed reaction of lignin fragments.16,

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41

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120.2/7.23, corresponding to Cα-Hα and Cβ-Hβ signals, in the spectra of spruce AL and KL. This

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structure was mainly produced from phenylcoumaran (β-5) unit after pulping treatment.15, 42

A little stilbene structure (H) can be identified at the correlations of δC/δH 128.0/7.08 and δC/δH

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Alkaline treatment of free phenolic β-O-4 structure produced styryl ether with two isomers:

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Ftrans and Fcis, and their corresponding cross-signals of Cα-Hα can be respectively observed at δC/δH

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112/6.11 and δC/δH 109.2/5.53 from the spectra of spruce AL and KL. The abundance of styryl ether

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unit was 13.2% (7.5% trans and 5.7% cis) in spruce AL, higher than the value (6.2%, including

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4.0% trans and 2.2% cis), in accordance with result of model reaction. Whereas, this structure was 13

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not detected in the eucalyptus AL. Presumably, in hardwood lignin most S unit are involved in

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etherified β-O-4 structure that are cleaved leading to phenylglycerol structures.41-42

277 HO  HO  

O4

HO  

5

OMe

A (-O-4)

OMe

5 



 O

B (-5)



C ()

E (-5)

OH 



2

6 5

279

F (Styryl ether)

X (Phenylglycerol)

OH HO 

O

J

H (Stilbene)

2

6

OMe O

278

OMe OH

HO  HO  OH 

OMe

O 

O



O 

MeO





MeO

OMe O

G

S

Polysacharides, Unassigned signals

Figure 2. Partial 2D HSQC NMR spectra of enzyme lignin (CEL), alkaline lignin (AL) and kraft lignin 14

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280 281

(KL) of spruce and eucalyptus. The content of structural moieties was determined by integrating the

282

As shown in Figure 2, the phenylglycerol structure (X) can be readily recognized in the

283

aliphatic oxygenated side chain region of the spectra according to NMR data obtained from

284

reference compounds discussed. It was reported that the Cβ-Hβ corelation overlaps with the C4-H4

285

correlation signal of xylan.16, 43 Xylan was not observed in the lignin spectra of eucalyptus materials

286

while it could be identified from the spectra of spruce AL. Integrating Cβ-Hβ signal can result in an

287

overestimation of glycerol content in spruce AL. The relative contents of phenylglycerol estimated

288

by using Cα-Hα signal were 8.9% and 8.6%, respectively for spruce AL and eucalyptus AL.

289

Although small amounts of phenylglycerol were produced in Kraft pulping of β-aryl ether model

290

compound, the phenylglycerol structures were not detected in eucalyptus KL. However, in the

291

spectrum of spruce KL, signal accounting for 1.5% was observed. This signal could be also

292

responsible for Ar-CHOH-COOH (J) in KL, because the Cα-Hα signal of J overlaps with the Cα-

293

Hα signal of phenylglycerol.16,

294

15% in alkaline pulping process (16.8% and 14.3% for spruce eucalyptus respectively, produced

295

from the destruction of β-O-4 linkages). It should be noted that the cleavage of β-aryl ether bond in

296

lignin polymer produces phenolic β-O-4 units which could undergo a different reaction pathway

297

from non-phenolic units, explaining much less phenylglycerol structures resulted from lignin than

298

those from model compounds (Scheme 1).

contours (C-H correlation signals of G2 and/or S2,6 were used as references).

43

On the other hand, the yield of phenylglycerol units was about

299

The 2D HSQC analysis of acetylated lignins also showed that ALs had much more

300

phenylglycerol structures than KLs (Figure S16, Table 2), which was consistent with the results by

301

HSQC analysis of original samples. Moreover, the content of glycerol structure in acetylated lignins

302

determined by 2D HSQC was higher than the value obtained from underivatized lignins (Table 1). 15

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303

The possible reason is that acetylation may have eliminated the hydrogen bonding associated with

304

glycerol sidechains, enhancing the intensity of corresponding correlation signals of NMR.

305

Nevertheless, it was still difficult to judge which way (acetylated or not) is better for quantifying

306

the phenylglycerol structure in lignins, because the intensity of C-H correlation signal in HSQC

307

spectrum is also affected by its chemical environments.

308 309

Table 2. Content of phenylglycerol end-groups in ALs and KLs determined by 2D HSQC NMR.

Types AL

KL

Eucalyptus

Spruce

Underivatized

8.6%

8.4%

Acetylated

13.4%

9.3%

Underivatized

nd

1.5%

Acetylated

nd

2.7%

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Overall, the ALs recovered by CO2 neutralization have been showed by 2D HSQC to contain

311

much more phenylglycerol structure than KLs. The content of glycerol structure in ALs was

312

determined to be in the range of 8% - 14% dependent on their origins and evaluation methods (Table

313

2). The relatively severe pulping conditions cleaving almost all of β-aryl ether bonds in the lignin

314

might be responsible for a higher phenylglycerol content compared to some mild conditions (under

315

which some ether bonds are retained). Moreover, it was reported that the content of glycerol

316

structure was higher in lignin with higher molecular weight.12 Washing with dichloromethane

317

removed some low molecular weight fraction of hardwood (eucalyptus) lignins in addition to the

318

extractives (Table S2, S3), resulting a higher molecular weight fraction with a slight high content

319

of phenylglycerol structure. Therefore, complete breakdown of the abundant β-aryl ether bonds of

320

lignin followed by fractionation with dichloromethane extraction could produce technical lignins

321

with relatively simple structure enriched in glycerol and resinols (peaks of some structure might 16

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overlap with signal of methoxy group, Figure S1). For lignin modifications to produce the value-

323

added products, many methodologies including esterification, phenolation etc. aim to functionalize

324

hydroxyl groups.3 Therefore the ALs with high amount of phenylglycerol end-groups could be a

325

favorable feedstock for such chemical modifications. This type of AL polymer with unique

326

structural characteristic would have distinct properties useful for further material applications.

327 328

4. CONCLUSIONS

329

Herein, the phenylglycerol structures in ALs were unambiguously identified and confirmed by

330

2D HSQC NMR with use of authenticated model compounds. It is suggested that phenylglycerol

331

structure mainly generated from the non-phenolic β-aryl ether bonds under Soda pulping process

332

rather than the kraft pulping process. 2D HSQC NMR analysis of ALs from both hardwood and

333

softwood feedstocks showed that fractionated (purified) ALs with higher molecular weight had

334

much more glycerol end-groups (8%-14%) in comparison to the KLs. NMR analysis of acetylated

335

lignins revealed higher content of glycerol structure than that of underivatized lignin samples. These

336

new findings are valuable for better understanding of lignin reactions during chemical pulping

337

process, which will be beneficial to lignin processing and valorization.

338 339

ASSOCIATED CONTENT

340

Supporting Information

341

2D HSQC spectra of eucalyptus alkaline lignin and the products from non-phenolic β-aryl ether

342

compound (Figure S1, S3); Synthesis of non-acetylated/acetylated G/S-glycerol compounds and

343

styryl ether compounds; 1H NMR and 2D HSQC NMR of synthetized compounds (Figure S4-S13); 17

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344

GC chromatograms of the products from reaction of model compounds (Figure S2, S14);

345

Calibration curves for quantification the products (Figure S15); 2D HSQC spectra of acetylated

346

alkaline and kraft lignins; Conditions for pulping processes (Table S1); Yield of recovered lignins

347

and their molecular weight distribution (Table S2, S3).

348 349

AUTHOR INFORMATION

350

Corresponding Author

351

✲ Corresponding

author: Fachuang Lu, E-mail: [email protected], Tel: +86 2-87113953

352 353

ORCID

354

Fachuang Lu: 0000-0002-6418-8992

355

Notes

356

The authors declare no competing financial interest.

357 358

ACKNOWLEDGEMENTS

359

The authors are grateful to the financial support for this work by the National Natural Science

360

Foundation of China (31770621), State Key Laboratory of Pulp and Paper Engineering (No.

361

2016TS03, 2018TS07, 201836), Guangdong Province Science Foundation for Cultivating National

362

Engineering Research Center for Efficient Utilization of Plant Fibers (2017B090903003) and the

363

Fundamental Research Funds for the Central Universities of SCUT, China (2018MS52).

364 365

REFERENCES 18

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(1) Boerjan, W.; Ralph, J.; Baucher, M., Lignin biosynthesis. Annu Rev Plant Biol 2003, 54, 519-46. (2) Vanholme, R.; Demedts, B.; Morreel, K.; Ralph, J.; Boerjan, W., Lignin biosynthesis and structure. Plant Physiol. 2010, 153 (3), 895-905. (3) Laurichesse, S.; Avérous, L., Chemical modification of lignins: Towards biobased polymers. Prog. Polym. Sci. 2014, 39 (7), 1266-1290. (4) Ragauskas, A. J.; Beckham, G. T.; Biddy, M. J.; Chandra, R.; Chen, F.; Davis, M. F.; Davison, B. H.; Dixon, R. A.; Gilna, P.; Keller, M.; Langan, P.; Naskar, A. K.; Saddler, J. N.; Tschaplinski, T. J.; Tuskan, G. A.; Wyman, C. E., Lignin valorization: improving lignin processing in the biorefinery. Science 2014, 344 (6185), 1246843. (5) Ferrini, P.; Rinaldi, R., Catalytic biorefining of plant biomass to non-pyrolytic lignin bio-oil and carbohydrates through hydrogen transfer reactions. Angew. Chem. Int. Ed. Engl. 2014, 53 (33), 8634-9. (6) Li, C.; Zhao, X.; Wang, A.; Huber, G. W.; Zhang, T., Catalytic Transformation of Lignin for the Production of Chemicals and Fuels. Chem. Rev. 2015, 115 (21), 11559-11624. (7) Schutyser, W.; Renders, T.; Van den Bosch, S.; Koelewijn, S. F.; Beckham, G. T.; Sels, B. F., Chemicals from lignin: an interplay of lignocellulose fractionation, depolymerisation, and upgrading. Chem. Soc. Rev. 2018, 47 (3), 852-908. (8) Shimada, K.; Hosoya, S.; Ikeda, T., Condensation Reactions of Softwood and Hardwood Lignin Model Compounds Under Organic Acid Cooking Conditions. J. Wood Chem. Technol. 1997, 17 (1-2), 57-72. (9) Chakar, F. S.; Ragauskas, A. J., Review of current and future softwood kraft lignin process chemistry. Ind. Crops Prod. 2004, 20 (2), 131-141. (10) Crestini, C.; Lange, H.; Sette, M.; Argyropoulos, D. S., On the structure of softwood kraft lignin. Green Chem. 2017, 19 (17), 4104-4121. (11) Wang, H.; Ben, H.; Ruan, H.; Zhang, L.; Pu, Y.; Feng, M.; Ragauskas, A. J.; Yang, B., Effects of Lignin Structure on Hydrodeoxygenation Reactivity of Pine Wood Lignin to Valuable Chemicals. ACS Sustainable Chem. Eng. 2017, 5 (2), 1824-1830. (12) Lancefield, C. S.; Wienk, H. L. J.; Boelens, R.; Weckhuysen, B. M.; Bruijnincx, P. C. A., Identification of a diagnostic structural motif reveals a new reaction intermediate and condensation pathway in kraft lignin formation. Chem. Sci. 2018, 9 (30), 6348-6360. (13) Gordobil, O.; Moriana, R.; Zhang, L.; Labidi, J.; Sevastyanova, O., Assesment of technical lignins for uses in biofuels and biomaterials: Structure-related properties, proximate analysis and chemical modification. Ind. Crops Prod. 2016, 83, 155-165. (14) Luo, H.; Abu-Omar, M. M., Lignin extraction and catalytic upgrading from genetically modified poplar. Green Chem. 2018, 20 (3), 745-753. (15) Capanema, E. A.; Balakshin, M. Y.; Chen, C.-L.; Gratzl, J. S.; Gracz, H., Structural Analysis of Residual and Technical Lignins by 1H-13C Correlation 2D NMR-Spectroscopy. Holzforschung 2001, 55 (3), 302-308. (16) Balakshin, M. Y.; Capanema, E. A.; Chen, C.-L.; Gracz, H. S., Elucidation of the Structures of Residual and Dissolved Pine Kraft Lignins Using an HMQC NMR Technique. J. Agric. Food Chem. 2003, 51, 6116-6127. (17) Heikkinen, S.; Toikka, M. M.; Karhunen, P. T.; Kilpeläinen, I. A., Quantitative 2D HSQC (QHSQC) via suppression of J-dependence of polarization transfer in NMR spectroscopy. J. Am. Chem. Soc. 2003, 125, 4362-4367. (18) Liitiä, T. M.; Maunu, S. L.; Hortling, B.; Toikka, M.; Kilpeläinen, I., Analysis of technical lignins 19

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Industrial & Engineering Chemistry Research 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

410 411 412 413 414 415 416 417 418 419 420 421 422 423 424 425 426 427 428 429 430 431 432 433 434 435 436 437 438 439 440 441 442 443 444 445

by twoand three dimensional NMR spectroscopy. J. Agric. Food Chem. 2003, 51 (8), 2136-2143.

446

Forest Prod. Lab., Madison, WI., 2001.

447 448 449 450 451 452

(35) Rinaldi, R.; Jastrzebski, R.; Clough, M. T.; Ralph, J.; Kennema, M.; Bruijnincx, P. C.; Weckhuysen,

(19) Ibarra, D., Chávez, M. I., Rencoret, J., Del Río, J. C., Gutiérrez, A., Romero, J, Lignin Modification during Eucalyptus globulus Kraft Pulping Followed by Totally Chlorine-Free Bleaching: A TwoDimensional Nuclear Magnetic Resonance, Fourier Transform Infrared, and Pyrolysis−Gas Chromatography/Mass Spectrometry Study. J. Agric. Food Chem. 2007, 55 (9), 3477-3490. (20) Hu, Z.; Du, X.; Liu, J.; Chang, H.-m.; Jameel, H., Structural Characterization of Pine Kraft Lignin: BioChoice Lignin vs Indulin AT. J. Wood Chem. Technol. 2016, 36 (6), 432-446. (21) Jiang, X.; Savithri, D.; Du, X.; Pawar, S.; Jameel, H.; Chang, H.-m.; Zhou, X., Fractionation and Characterization of Kraft Lignin by Sequential Precipitation with Various Organic Solvents. ACS Sustainable Chem. Eng. 2016, 5 (1), 835-842. (22) Kubo, S.; Hashida, K.; Hishiyama, S.; Yamada, T.; Hosoya, S., Possibilities of the Formation of Enol-Ethers in Lignin by Soda Pulping. J. Wood Chem. Technol. 2014, 35 (1), 62-72. (23) Constant, S.; Wienk, H. L. J.; Frissen, A. E.; Peinder, P. d.; Boelens, R.; van Es, D. S.; Grisel, R. J. H.; Weckhuysen, B. M.; Huijgen, W. J. J.; Gosselink, R. J. A.; Bruijnincx, P. C. A., New insights into the structure and composition of technical lignins: a comparative characterisation study. Green Chem. 2016, 18 (9), 2651-2665. (24) Yue, F.; Lu, F.; Ralph, S.; Ralph, J., Identification of 4-O-5-Units in Softwood Lignins via Definitive Lignin Models and NMR. Biomacromolecules 2016, 17 (6), 1909-20. (25) Froass, P. M.; Ragauskas, A. J.; Jiang, J.-e., Nuclear Magnetic Resonance Studies. 4. Analysis of Residual Lignin after Kraft Pulping. Ind. Eng. Chem. Res. 1998, 37, 3388-3394. (26) Marton, J., Lignins: occurrence, formation, structure and reactions. Wiley-Interscience: Toronto, 1971; Vol. 16. (27) Berlin, A.; Balakshin, M., Industrial Lignins: Analysis, Properties, and Applications. In Bioenergy Research: Advances and Applications, Elsevier, 2014; pp 315-336. (28) Gierer, J., Chemical Aspects of Kraft Pulping. Wood Sci. Technol. 1980, 14 (4), 241-266. (29) Gierer, J., Chemistry of delignification. Wood Sci. Technol. 1985, 19 (4), 289-312. (30) Regner;, M.; Bartuce;, A.; Padmakshan;, D.; Ralph;, J.; Karlen, S. D., Reductive cleavage method for quantitation of monolignols and low‐abundance monolignol conjugates. ChemSusChem 2018, 11, 1600-1605. (31) Yue, F.; Lu, F.; Sun, R. C.; Ralph, J., Syntheses of lignin-derived thioacidolysis monomers and their uses as quantitation standards. J. Agric. Food Chem. 2012, 60(4), 922-928. (32) Chang, H. M.; Cowling, E. B.; Brown, W., Comparative studies on cellulolytic enzyme lignin and milled wood lignin of sweetgum and spruce. Holzforschung 1975, 29 (5), 153-159. (33) Gellerstedt G. Chemistry of chemical pulping. In Pulping chemistry and technology, De Gruyter, 2009, 2: 91-120. (34) Ralph, S.; Landucci, L.; Ralph, J., NMR Database of Lignin and Cell Wall Model Compounds. US

B. M., Paving the Way for Lignin Valorisation: Recent Advances in Bioengineering, Biorefining and Catalysis. Angew. Chem. Int. Ed. Engl. 2016, 55 (29), 8164-8215. (36) Nagy M.; Kosa M.; Theliander H.; Ragauskas A.J., Characterization of CO2 precipitated Kraft lignin to promote its utilization. Green Chem. 2010, 12(1), 31-34. (37) Alekhina M.; Ershova O.; Ebert A.; Heikkinen S.; Sixta H., Softwood kraft lignin for value-added 20

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453 454 455 456 457 458 459 460 461 462 463 464 465 466 467 468 469 470 471 472 473

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applications: Fractionation and structural characterization. Ind. Crops Prod. 2015, 66, 220-228. (38) Ralph, J.; Akiyama, T.; Kim, H.; Lu, F.; Schatz, P. F.; Marita, J. M.; Ralph, S. A.; Reddy, M. S.; Chen, F.; Dixon, R. A., Effects of coumarate 3-hydroxylase down-regulation on lignin structure. J. Biol. Chem. 2006, 281 (13), 8843-8853. (39) Prinsen, P.; Rencoret, J.; Gutiérrez, A.; Liitiä, T.; Tamminen, T.; Colodette, J. L.; Berbis, M. Á.; Jiménez-Barbero, J.; Martínez, Á. T.; del Río, J. C., Modification of the Lignin Structure during Alkaline Delignification of Eucalyptus Wood by Kraft, Soda-AQ, and Soda-O2 Cooking. Ind. Eng. Chem. Res. 2013, 52 (45), 15702-15712. (40) Nieminen, K.; Kuitunen, S.; Paananen, M.; Sixta, H., Novel Insight into Lignin Degradation during Kraft Cooking. Ind. Eng. Chem. Res. 2014, 53 (7), 2614-2624. (41) Shimizu, S.; Yokoyama, T.; Akiyama, T.; Matsumoto, Y., Reactivity of lignin with different composition of aromatic syringyl/guaiacyl structures and erythro/threo side chain structures in beta-O-4 type during alkaline delignification: as a basis for the different degradability of hardwood and softwood lignin. J. Agric. Food Chem. 2012, 60 (26), 6471-6476. (42) Shimizu, S.; Yokoyama, T.; Matsumoto, Y., Effect of type of aromatic nucleus in lignin on the rate of the β-O-4 bond cleavage during alkaline pulping process. J. Wood Sci. 2015, 61 (5), 529-536. (43) Martín-Sampedro R.; Santos J. I.; Fillat Ú.; Wicklein B.; Eugenio M.; Ibarra D., Characterization of lignins from Populus alba L. generated as by-products in different transformation processes: Kraft pulping, organosolv and acid hydrolysis. Int. J. Biol. Macromol. 2019, 126, 18-29.

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485 486 487 488

Abstract graphic:

489 490 491

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graphic abstract

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Figure 1. Partial 2D HSQC NMR spectra of non-acetylated/acetylated eucalyptus alkaline lignin (AL) and phenylglycerol compounds for peak assignment. The unknown peaks in (A) eucalyptus AL were compared with the peaks from (B) G-gly and (C) S-gly. The phen¬ylglycerol structure in AL was also confirmed by matching the peaks from acetylated compounds and acetylated AL (D). 169x125mm (300 x 300 DPI)

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Scheme 1. Quantitative analysis of the products from β-O-4 compounds after alkaline and kraft treatments. The yields of products were determined by external standard method based on the mole quantity of reacted dimer (Figure S14 and S15). Less syringyl monomer was detected compared to the formation of phenylpropyl derivatives after alkaline treatment, potentially due to some condensation reactions involving syringyl monomers. 123x88mm (300 x 300 DPI)

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Figure 2. Partial 2D HSQC NMR spectra of enzyme lignin (CEL), alkaline lignin (AL) and kraft lignin (KL) of spruce and eucalyptus. The content of structural moieties was determined by integrating the contours (C-H correlation signals of G2 and/or S2,6 were used as references). 107x120mm (300 x 300 DPI)

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