High-solid Lignocellulose Processing Enabled by Natural Deep

Jul 31, 2018 - This study investigated high-solid loading deep eutectic solvent (DES) pretreatment for lignocellulose fractionation and subsequent con...
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High-solid Lignocellulose Processing Enabled by Natural Deep Eutectic Solvent for Lignin Extraction and Industrially Relevant Production of Renewable Chemicals Zhu Chen, Xianglan Bai, Lusi A, and Caixia Wan ACS Sustainable Chem. Eng., Just Accepted Manuscript • DOI: 10.1021/acssuschemeng.8b02541 • Publication Date (Web): 31 Jul 2018 Downloaded from http://pubs.acs.org on August 5, 2018

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ACS Sustainable Chemistry & Engineering

High-solid Lignocellulose Processing Enabled by Natural Deep Eutectic Solvent for

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Lignin Extraction and Industrially Relevant Production of Renewable Chemicals

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Zhu Chen a, Xianglan Bai b, Lusi Ab, Caixia Wan a,* a

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Columbia, Missouri 65211, USA

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Department of Bioengineering, University of Missouri, 1406 East Rollins Street,

b

Department of Mechanical Engineering, Iowa State University, 2529 Union Drive, Ames, IA 50011, USA *

Corresponding author: Phone: +1 573 884 7882; Fax: +1 573 884 5650; E-mail: [email protected]

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ABSTRACT: This study investigated high-solid loading deep eutectic solvent (DES)

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pretreatment for lignocellulose fractionation and subsequent conversion into platform

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chemicals (i.e., furfural, 2,3-butanediol). Switchgrass was pretreated with choline

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chloride:ethylene glycol (ChCl:EG) under acidic condition at high solid loadings of 20%

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and 27%. Cellulose was enriched to as high as 72.6% in pretreated switchgrass due to

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substantial removal of lignin and xylan but minor cellulose loss. Highly concentrated sugar

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hydrolysate containing up to 241.2 g/L of fermentable sugars (206.5 g/L of glucose and

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34.7 g/L of xylose) with 86.2% glucose yield was obtained from pretreated switchgrass via

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25% solid loading enzymatic hydrolysis for only 48 h. The high sugar concentration

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allowed the production of 90.2 g/L of 2,3-butanediol upon fermentation, a record high titer

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produced from lignocellulose hydrolysate without additional sugar concentration. ChCl:EG

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showed good recyclability and its re-use facilitated lignin recovery from pretreatment

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liquor. The pretreatment liquor resulting from 4 pretreatment cycles was enriched with 96.8

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g/L of xylan-based sugars, of which 84.6% was converted to furfural. 2D HSQC NMR 1

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revealed that β-O-4 interunit linkage experienced substantial cleavage during the

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pretreatment. The degree of bond cleavage depended on the solid loading for pretreatment.

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Lignin derived from a higher solid loading pretreatment preserved the original structure of

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natural lignin better, thus producing increased amounts of phenolic monomers upon

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pyrolysis. This study demonstrated that high-solid loading, ChCl:EG pretreatment was not

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only effective for biomass fractionation but also enabled industrially relevant production of

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concentrated sugar hydrolysate, furfural, and 2,3-butanediol.

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KEYWORDS: Deep eutectic solvent, pretreatment, enzymatic hydrolysis, lignin,

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2,3-butanediol, furfural

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INTRODUCTION

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Biofuels and bio-based chemicals from lignocellulosic biomass can replace

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petroleum-based counterparts. For a biorefinery based on a biochemical conversion

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platform, a pretreatment step is often required to overcome the recalcitrance of

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lignocellulosic biomass and to facilitate the release of fermentable sugars. In the past two

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decades, great efforts have been devoted to developing a pretreatment that maximizes

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cellulose digestibility. However, the vast majority of lignin is treated as a waste and burned

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as low-grade solid fuel for biorefinery plants. To make biorefinery lignin a profitable

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product, one prerequisite is to extract valorizable lignin with high yield from

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lignocellulosic biomass. In addition to lignin, liquid waste should be minimized and

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post-treated/explored further for value-added conversion. Pretreatment solvent recycling

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would not only save costs for chemicals but also minimize waste stream generation. 2

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Another benefit with solvent recycling is enrichment of solubilized sugars in pretreatment

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liquor, which would make them concentrated enough for further upgrading, such as lipid

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and furfural production.1 Therefore, a successful biorefinery should be enabled by

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economically viable and environmentally sustainable technologies to supply market-driven

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products.2

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Using high solid loadings at 15% or above in the unit operations of lignocellulose

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conversion, such as pretreatment and enzymatic hydrolysis, could improve production

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efficiency, reduce energy consumption, ease downstream processing, reduce waste

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generation, and lower the overall processing cost.3 For ethanol production, an ethanol titer

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of 50 g/L or above is desired for industrial scale, which requires at least 10% glucan

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loading for enzymatic hydrolysis.4-5 Similar scenario is applied to another versatile

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platform chemical – 2,3-butanediol (2,3-BD) which has a broad industrial application.6

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Cellulosic 2,3-BD titers reported seldom exceeds 50 g/L unless sugar hydrolysate is

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purposely concentrated prior to fermentation through costly membrane filtration or

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energy-intensive approach.6-8 With an increasing market “pull” for 2,3-BD, especially as a

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precursor for tire manufacturing, it is important to achieve more industrially relevant titer,

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yield, and productivity (TYP). However, high-solid loading enzymatic hydrolysis remains

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challenging due to substrate inhibition and mass transfer limitations.9 Likewise, limited

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mass transfer could arise from high solid loading pretreatment. Therefore, pursuing high

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solid loadings for both enzymatic hydrolysis and pretreatment would be more challenging

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but highly rewarding.

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DESs are emerging designer solvents for lignocellulose pretreatment. Among the 3

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numerous DESs reported so far, natural DESs with biomass-derived polyols as hydrogen

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bond donors, especially choline chloride:ethylene glycol (ChCl:EG), hold great promise for

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lignocellulosic biomass pretreatment due to its good solubility of lignin, low vapor pressure,

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and viscosity.10-11 In addition, ChCl:EG has been shown to stabilize enzymes and be

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compatible with microorganisms,12-14 which provides a basis for designing one-pot

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biochemical reaction. Compared with other DESs (e.g., ChCl:Urea), ChCl:EG could also

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serve as an excellent medium for electrochemical depolymerization of lignin,11 suggesting

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the feasibility of adopting a simplified route for lignin valorization by integrating lignin

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extraction and upgrading in a single solvent. However, lignocellulose fractionation by

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ChCl:EG has been shown to be a slow process.13, 15 Our previous study indicated that

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polyol-based DES (i.e., ChCl:glycerin) became highly effective under an acidic

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environment which was much milder than conventional dilute acid pretreatment.1 Acidic

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DESs composed of ChCl and carboxylic acids (e.g., formic acid, lactic acid) also showed

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impressive performance.15-16 Possible mechanism for enhanced delignification and

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hemicellulose removal by acidified/acidic DESs is the better availability and reactivity of

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acidic protons in a DES environment, which is critical for acid-catalyzed cleavage of

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numerous bonds (e.g., ether bonds, ester bonds, lignin-polysaccharide interlinkages) in

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lignocellulose complex. Another benefit of using polyol-based natural DES in acidic

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environment is avoiding possible side reactions, like esterification between carboxylic

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acid-based DESs and cellulose, which could limit cellulose digestibility to a great extent.

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Our studies on polyol-based natural DESs under acidic environment (also called acidified

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DESs) would broaden the spectrum of DESs for lignocellulose processing, identify 4

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high-performance DES-based pretreatment solvents, and provide insights into DES-enabled

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lignocellulose fractionation.

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The objective of this study was to develop a high solid loading, ChCl:EG pretreatment

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for viable lignocellulose processing. Using switchgrass as a model feedstock, the effects of

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acid, water, and solid loading on ChCl:EG pretreatment were studied. The solvent

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recyclability and reusability were also evaluated. Moreover, pretreated switchgrass was

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tested for concentrated sugar production and further conversion into 2,3-BD. We also

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investigated the enrichment of xylan-based sugars in pretreatment liquor upon solvent

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recycling and subsequent liquor upgrading into furfural.

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EXPERIMENTAL SECTION

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Materials. Switchgrass was collected from the South Farm at University of Missouri

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in Columbia, Missouri, USA. Raw switchgrass was air-dried, ground through a 2 mm-mesh

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screen, and stored in an airtight container. It contained 34.5% glucan, 23.3% xylan, and

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20.4% lignin. Hydrolytic enzymes (Cellic® CTec2 and HTec2) were kindly provided by

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Novozyme (Franklinton, NC, USA). All the chemicals were purchased from Fisher

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Scientific (Hampton, NH, USA).

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DES Synthesis. ChCl was dried at 80 ºC for 6 h and cooled to room temperature in a

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desiccator prior to use. Neat ChCl:EG was synthesized by mixing ChCl and EG at a molar

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ratio of 1:2 and heating the mixture at 60 ºC with continuous stirring (200 rpm) until a

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transparent solvent was formed. Aqueous ChCl:EG containing 10 wt% and 20 wt% water

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was prepared by adding deionized (DI) water to neat ChCl:EG. Acidified neat or aqueous

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ChCl:EG contained 1.0 wt% H2SO4. 5

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DES pretreatment and lignin recovery. For DES pretreatment, 10 g of dry

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switchgrass was mixed with acidified neat or aqueous ChCl:EG in a 250 mL glass bottle.

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The bottle was then placed in a preheated oil bath with manual mixing every 5 min using a

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PTFE rod. The pretreatment with 10 wt% solid loading was conducted at 130 ºC for 30 min.

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For the pretreatment at high solid, two conditions were tested: (a) 130 ºC, 30 min, 20 wt%

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solid loading (P20); and (b) 130ºC, 45 min, 27 wt% solid loading (P27). At the end of

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pretreatment, the bottle was taken out of the oil bath immediately, and cooled to room

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temperature. Then, 50 mL of acetone:water (50:50, v/v) was added to the bottle followed

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by vacuum filtration. The solid residue was washed with 25 mL of acetone:water (50:50,

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v/v) four times and then stored at -20 ºC for further use. Acetone:water (50:50, v/v) was

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chosen as a washing solvent as this mixture is miscible with ChCl:EG, and acetone can be

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easily removed via vacuum evaporation or recovered via distillation due to its low boiling

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point.

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The filtrate collected from the slurry separation and the washing of the pretreated

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solids were combined and evaporated to remove acetone via vacuum evaporation. Lignin

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was precipitated after acetone removal, collected via centrifugation at 10,000 ×g for 5 min,

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and further washed with 15 mL of ethanol:water (1:9, v/v) four times. Lastly, lignin was

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dried at 45 ºC in a convection oven for 12 h and stored in an airtight glass container at

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room temperature. To recycle ChCl:EG, the above liquor was evaporated at 70 ºC in a

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convection oven to remove excess water. The recycled ChCl:EG was supplemented with

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acid to make its pH equal to that of the freshly prepared acidified ChCl:EG, and then used

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for a new pretreatment cycle. Lignin yield was defined as lignin recovered from a single 6

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pretreatment cycle with respect to lignin solubilized from the same cycle. Cumulative

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lignin yield was calculated based on cumulative pretreatment cycles.

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Enzymatic hydrolysis. Enzymatic hydrolysis was conducted at 50 ºC and 150 rpm for

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24 h, unless otherwise stated. CTec2 and HTec2 were loaded at 20 and 2 mg protein/g solid,

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respectively, to citrate buffer (final concentration of 50 mM, pH 5.5). The pH value of 5.5

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was selected for enzymatic hydrolysis as it is within the optimum range (pH 5.0-5.5) for

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CTec2 and would minimize the alkaline consumption for bringing pH to a higher level (pH

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7) for 2,3-butadediol fermentation. Low solid loading was 2 wt% and high solid loadings

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were 20 wt% and 25 wt%. The hydrolysate was boiled for 5 min to deactivate the enzymes

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and then centrifuged at 17,000 ×g for 2 min. The supernatant was collected and stored at

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-20 ºC prior to analysis. Sugar yield was defined as a percentage of theoretical sugar yield

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of untreated/pretreated biomass. All tests were run at least in duplicate. The data were

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reported as mean values with standard deviation.

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2,3-Butanediol (2,3-BD) fermentation. Bacillus vallismortis (NRRL B-14891) used

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for 2,3-BD fermentation was kindly provided by the United States Department of

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Agriculture (USDA) Agriculture Research Service (ARS) Culture Collection (Peoria, IL).

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The strain was routinely maintained on Luria-Bertani (LB) agar plate containing 10 g/L

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tryptone, 5 g/L yeast extract, 10 g/L NaCl, and 15 g/L agar. The seed culture was prepared

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by growing the strain in 50 mL of LB medium for 12 h at 30 °C and 200 rpm. The cellular

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biomass was collected via centrifugation at 5,000 ×g for 5 min, washed twice with 0.9%

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saline solution, and then re-suspended in the saline solution. The re-suspended cells were

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then inoculated into 20 mL of fermentation medium to obtain an initial optical density (OD) 7

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at 600 nm of 0.2. The fermentation medium contained (g/L): KH2PO4 4, tryptone 5, yeast

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extract 10, (NH4)2SO4 1, MgSO4·7H2O 0.75, and CaCl2·2H2O 0.1. The hydrolysate

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resulting from 20% and 25% solid loading enzymatic hydrolysis of switchgrass pretreated

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at 20% solid loading, as described in Section 2.4, was used as the substrate. The pH of

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fermentation media was adjusted to 7 every 12 h using 5 M NaOH. The pH probe was

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sterilized with 70% ethanol, and dried under an aseptic condition in a biological safety

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chamber before use. The fermentation was conducted in 125 mL Erlenmeyer flask plugged

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with foam stopper in an incubator shaker at 30 °C and 200 rpm for 72 h. The samples were

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taken every 12 h and analyzed for the titers of sugar and 2,3-BD using HPLC. To

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compensate water loss due to evaporation, sterile DI water was added every 12 h before

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sampling and pH adjustment. The fermentation tests were run at least in duplicate. The data

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were reported as mean values with standard deviation.

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Furfural production. Furfural production was conducted in a pressure tube using a

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biphasic reaction system comprising 1 mL of aqueous sample and 4 mL methyl isobutyl

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ketone (MIBK). The pressure tube was placed in a preheated oil bath at 160 ℃ for 40 min.

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Aqueous ChCl:EG (50 wt% water) containing 100 g/L xylose was first used for the

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determination of optimal AlCl3 loading. A varying level of AlCl3 ranging from 0.38 to 3.00%

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w/v loading was tested. The pretreatment liquor was tested as both a reaction medium and

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substrate for furfural production under the same reaction condition with the optimized

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AlCl3 loading.

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Analytical methods. The compositional analysis, lignin purity analysis, and glucose/xylose oligomers determination in pretreatment liquor were conducted following 8

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NREL laboratory protocols.17-18 Lignin purity was calculated as the total amount of acid

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soluble lignin (ASL) and acid insoluble lignin (AIL) relative to the dry mass of recovered

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lignin. Sugar concentration was determined using a high performance liquid

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chromatography (HPLC) Agilent 1200 series (Agilent Technologies, Palo Alto, USA)

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equipped with a refractive index detector (RID) and a HPX-87P column (300 × 7.8 mm)

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(Bio-Rad, Hercules, USA) as described in our previous study.19

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Furfural titers in both aqueous phase and MIBK phase were determined using the

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above HPLC system but equipped with a ZORBAX Eclipse XDB-C18 column (150 × 4.6

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mm) (Agilent Technologies, Palo Alto, USA). The mobile phase was 20 vol% methanol,

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eluting at a flow rate of 1 mL/min. The temperatures of the RID and column were

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maintained at 30 and 35 ℃ respectively. For the determination of 2,3-BD and EG,

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HPX-87H column (300 × 7.8 mm) (Bio-Rad, Hercules, USA) was used. The temperatures

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of the RID and column were kept at 40 and 65 ºC, respectively. H2SO4 (5mM) was used as

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the mobile phase with a flow rate of 0.6 mL/min.

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2D HSQC NMR analysis of native lignin and lignin resulting from DES pretreatment

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was conducted as described in our previous study.19 Native lignin was prepared and purified

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as described previously.20 The detailed procedures were provided in the Supporting

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Information. P-coumarate (pCA), ferulate (FA), and β-O-4 abundance were estimated

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semi-quantitatively using the volume integration of contours in HSQC spectra.21

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Gel permeation chromatography (GPC) was performed to determine the molecular

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weight distribution of lignin. Prior to GPC analysis, the lignin samples were acetylated to

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increase their solubility in tetrahydrofuran (THF). For acetylation, 100 mg of lignin along 9

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with 3 mL pyridine and 3 mL acetic anhydride were added to a glass vial. The vial was then

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heated in oil bath at 80 °C for 3 h with continuous stirring. After acetylation, 500 mL of DI

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water was added to the solution to precipitate acetylated lignin. The precipitated lignin was

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washed with DI water for three times to remove residual chemicals. To prepare GPC sample,

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20 mg of acetylated lignin was dissolved in 10 mL THF and then purified using a 0.45 µm

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filter to remove any solid particles. The GPC analysis was performed in a Dionex Ultimate

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3000 series high performance liquid chromatography (HPLC) equipped with a Shodex

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Refrative Index (RI) detector and Diode Array Detector (DAD). Two Agilent PLgel 3 µm

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100A0 300 × 7.5 mm (p/n PL1110-6320) were connected in series in the HPLC and the flow

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rate of THF was 1mL/min. The GPC column was pre-calibrated with polystyrene standards

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with molecular weights from 162 to 45120 g/mol, and ultraviolet wave length of 254 nm was

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used to analyze the molecular weight distribution. The GPC analysis was duplicated for each

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lignin sample.

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Thermal stability of lignin was determined using a Mettler Toledo thermogravimetric

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analysis system (TGA/DSC 1 STAR system). Approximately 20 mg of lignin sample was

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placed in a crucible and heated under a nitrogen environment from room temperature to

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105 °C at 10 °C/min and then hold for 40 min to remove the moisture. The sample was

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continuously heated to 900 °C. The analysis was duplicated for each lignin sample.

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Fast pyrolysis of lignin was conducted using a Frontier Lab Tandem micropyrolyzer

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(Tx-3050 TR) with an auto sampler. The configuration of the reactor is described in

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previous literature.20 Briefly, the micro-pyrolyzer consists of two furnaces connected in

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series. During the tests, 500 µg of lignin was placed in a deactivated stainless-steel cup and 10

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pyrolyzed in the top furnace at 500 °C using helium as a carrier gas. The temperature of the

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lower furnace was maintained at 350 °C to prevent the condensation of the pyrolysis vapor.

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The pyrolysis vapors leaving the micro-pyrolyzer were directly swept into Agilent 7890B

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GC/MS-FID-TCD for instantaneous product analysis. Helium was also used as the purge

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gas in the GC. The flow rate of helium was 156 mL/min and the split ratio at the front-inlet

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was 50:1. The temperature of the GC oven was kept at 40 °C for 3 min, and then increased

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to 280 °C at a heating rate of 6 °C/min. Finally, the GC was held at 280 °C for 3 min. Two

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Phenomenex ZB 1701 (60 m × 0.250 mm × 0.250 µm) columns were used for the MS and

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FID, and a Porous Layer Open Tubular (PLOT) (60 m × 0.320 mm) was used for the TCD.

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The monomers identified by the MS were quantified by FID. The FID calibration curves

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were created by injecting five different concentrations of each compound into the GC. The

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pyrolysis test was triplicated for each lignin sample and the averaged results were reported.

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RESULTS AND DISCUSSION

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Effects of acidification on the pretreatment performance of ChCl:EG. The

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pretreatment effectiveness of acidified ChCl:EG was compared with neat ChCl:EG,

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acidified EG, and dilute acid solution. As shown in Figs.1a and S1, neat ChCl:EG removed

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24% of lignin but had minor effects on glucan and xylan, indicating the high selectivity of

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ChCl:EG on lignocellulose fractionation. Similar results were also reported by a prior study

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using ChCl:EG to pretreat corncob.15 Once ChCl:EG was acidified, lignin and xylan

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removal increased to about 87% and 82% (Fig.1a), respectively. Although acid solution

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only (1.0% H2SO4) led to more xylan and lignin removal than neat ChCl:EG, its

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performance was not comparable with acidified ChCl:EG. In consistence with prior study,22 11

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acidified EG was effective for lignin and xylan removal, demonstrating a similar

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performance to acidified ChCl:EG with regard to lignin and xylan removal. These results

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suggested a strong synergism between acid and ChCl:EG in the pretreatment of switchgrass.

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Similar synergism has also been demonstrated by several organic solvent systems, such as

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γ‐valerolactone, dioxane, and tetrahydrofuran.4, 23-24 Comparing different solvent systems

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especially under a mild reaction condition, H2SO4 may be less active in water to donate

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proton for bond cleavage due to the solvation of acidic proton by water molecule.23 Similar

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to the aforementioned organic solvent systems, ChCl:EG should provide a favorable

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environment to make acidic proton more available and reactive for lignocellulose

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fractionation.

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XRD analysis was done to understand the structural change of switchgrass in response

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to different pretreatments. As shown in Fig.S2, switchgrass pretreated with neat ChCl:EG

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had a CrI of 54, which was same as that of the untreated one. For H2SO4 only-pretreated,

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acidified EG and acidified ChCl:EG-pretreated switchgrass, the CrI increased to 62, 71,

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and 66, respectively, indicating increased crystalline cellulose contents after pretreatment.

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The changes in surface functional groups of switchgrass in response of pretreatment was

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revealed by FTIR (Fig.S3). Typical peaks of cellulose were found at 900 cm-1 (C-H

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deformation in cellulose), 1100 cm-1 (C-O vibration in crystalline cellulose), 1035 and

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1056 cm-1 (C-O stretching of cellulose), and 1160 cm-1 (C-O-C asymmetric stretching in

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cellulose).25 These cellulose peaks showed a higher intensity in acidified EG and ChCl:EG

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pretreated switchgrass, suggesting a enrichment of cellulose in the sample. Characteristic

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peaks related to lignin, such as 1510 cm-1 (aromatic skeletal vibrations) and 1240 cm-1 (C-O 12

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vibration in the syringyl ring), was evident in the untreated, ChCl:EG-pretreated, and acid

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only-pretreated switchgrass, but became much weaker in the acidified EG and

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ChCl:EG-pretreated ones, suggesting a lower lignin content in these samples.26

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The digestibility of pretreated switchgrass was evaluated by conducting enzymatic

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hydrolysis with 2 wt% solid loading for 24 h. Switchgrass pretreated with neat ChCl:EG

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had glucose and xylose yields of 11% and 2%, respectively, which were similar to those of

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the untreated switchgrass (Fig.1b). Acid only pretreatment (1% H2SO4) improved the

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glucose yield from 11% to 37% and the xylose yield from 2% to 25%. In contrast, both

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acidified EG and ChCl:EG resulted in a near theoretical sugar yield (Fig.1b). Such high

275

sugar yields could be attributed to the significant removal of xylan and lignin, which

276

enhanced the accessibility of cellulose to hydrolytic enzymes. The highest glucose yield

277

reported so far via DESs pretreatment was 99% for corn stover pretreated by ChCl:formic

278

acid for 3 h at 130 ℃ using 5% solid loading.16 Other DESs, including ChCl:urea,

279

ChCl:glycerol, ChCl:acetic acid, ChCl:oxalic acid, and ChCl:malonic, gave glucose yields

280

much lower than 90% even under similar pretreatment conditions.16 Over 90% glucose

281

yield of ChCl:Glycerin-pretreated corn cob was reported by Procentese et al.,27 but the

282

pretreatment required a quite severe condition (150 ℃ for 15 h) even at 6% solid loading.

283

Acidified ChCl:EG outperformed most DES pretreatments in terms of pretreatment

284

efficiency and effectiveness as well as biomass digestibility. In addition, the pretreatment

285

based on acidified ChCl:EG required less severe conditions (shorter time and/or lower

286

temperature), while the solid loading was comparable with or even higher than most

287

reported DES pretreatments.16, 27 Overall, acidified ChCl:EG was highly efficient for xylan 13

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288

and lignin removal, and the resultant cellulose-enriched residue/pulp was highly digestible

289

as discussed in the latter section.

290

High-solid loading pretreatment. Since acidified ChCl:EG was able to substantially

291

remove lignin and subsequently increase the digestibility of switchgrass, its performance

292

on the pretreatments with a much higher solid loading (i.e., 20%, 27%) was explored.

293

Acidified ChCl:EG still showed good performance at 20% and 27% loading, although

294

lignin and xylan removal decreased with an increase in solid loading for pretreatment

295

(Figs.2&S4). Some prior studies have demonstrated that water addition could lower the

296

viscosity of DESs, enhance lignin extraction, and reduce cellulose loss.28-29 Consequently,

297

the effects of water addition on the pretreatment performance of acidified ChCl:EG were

298

also investigated. For 20% solid loading pretreatment, water addition at 10% and 20%

299

appeared to not impact the fractionation performance of acidified ChCl:EG, since similar

300

lignin and xylan removal, about 80% and 75%, respectively, were achieved. In contrast, at

301

a higher solid loading (27%), acidified, aqueous ChCl:EG containing 10% water removed

302

smaller amounts of lignin and xylan but with similar degrees to acidified, neat ChCl:EG

303

(Fig.2a). At the same solid loading, acidified, aqueous ChCl:EG containing more water

304

(20%) solubilized less lignin and xylan from switchgrass. Under all the circumstances,

305

more than 95% of glucan was preserved. In consistence with the results for 10% solid

306

loading pretreatment as discussed in Section 3.1, acidified ChCl:EG selectively removed

307

lignin and xylan while preserving most cellulose.

308

Given significant xylan and lignin removal at high solid loading, it was expected that

309

the sugar yield could be greatly enhanced. As shown in Fig.2b, the glucose yields showed 14

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little variation in response to water addition during the pretreatment at 20% solid loading,

311

reaching about 95%. It is suggested that the digestibility of pretreated biomass should be

312

largely dependent on the degree of delignification and/or the properties of lignin remaining

313

in pretreated biomass.30 For example, switchgrass with a delignification over 60% via

314

either ionic liquid pretreatment or alkaline pretreatment gave a glucose yield above 95%

315

after 24 h enzymatic hydrolysis.30-31 Given that more than 70% lignin was removed from

316

switchgrass during all the pretreatment tested at 20% solid, it was not surprising to find that

317

all the subsequently glucose yields reached near 95% with little variation. When the solid

318

loading for pretreatment increased to 27%, the glucose yield remained above 90% but was

319

2-5% lower than those from 20% solid loading pretreatment (Fig.2b). Compared with

320

glucose yields, xylose yields were near 10% lower, reaching approximately 85% and 80%

321

for 20% and 27% solid loading pretreatments, respectively (Fig.2b).

322

Solvent recycling after pretreatment would improve not only waste management but

323

also reduce chemical consumption and enrich soluble compounds. Therefore, it is worth

324

evaluating the recyclability and reusability of ChCl:EG. It has been suggested that

325

impurities (e.g., lignin derived phenolics, degraded carbohydrates) generated during

326

pretreatment are a major factor affecting DES pretreatment performance.32 To test the

327

robustness of ChCl:EG, a solid loading of 27%, which would generate a high level of

328

impurities, was selected for solvent recycling test. Acidified, aqueous ChCl:EG containing

329

10% water was selected as it gave similar lignin and xylan removal to neat ChCl:EG but

330

was better than the one with 20% water (Figs.2a). Xylan removal remained almost

331

unchanged throughout all the pretreatment cycles, reaching about 70% (Fig.3a). Lignin 15

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removal was about 70% for the first three cycles but decreased to 60% in the fourth cycle.

333

Glucan removal showed an increase from 2.5% to 6% from the first cycle to the third one,

334

and the resultant residue showed a decrease in glucan content from 68% to 62% (Fig.3a). In

335

terms of digestibility, about 90% glucose yield was obtained during all the cycles, while the

336

xylose yield was approximately 80% from the first to third cycle and decreased to 70%

337

after the fourth cycle (Fig.3b). Overall, aqueous ChCl:EG was successfully recycled and

338

reused for at least three more cycles with similar performance. Upon the accumulation of

339

impurities (e.g., lignin-derived compounds, soluble sugars) over the increased cycles,

340

conditioning the recycled solvents would be necessary in order to improve its reusability.

341

Lignin-derived compounds can be removed from the recycled solvent via adsorptive resin

342

and membrane filtration.33 Soluble sugars can be removed via in situ upgrading into

343

platform chemicals such as furfural as reported in the latter section.

344

High solid loading enzymatic hydrolysis. Concentrated sugar hydrolysate production

345

without additional concentration, conditioning, or purification steps could realize high titers

346

of cellulosic fuels, reducing distillation capital, and operating costs.5 Therefore, high solid

347

loading enzymatic hydrolysis (20% and 25%) was conducted to evaluate the feasibility of

348

producing hydrolysate with highly concentrated monomeric sugars. Switchgrass pretreated

349

at 20% and 27% solid loading using acidified, aqueous ChCl:EG (10% water) was used for

350

evaluation. Switchgrass pretreated at 20% solid loading gave a glucose and xylose yield of

351

85.2% and 75.3%, respectively, after only 48 h of enzymatic hydrolysis, and the resulting

352

hydrolysate contained 164.4 g/L of glucose and 25.5 g/L of xylose (Fig.4). When the solid

353

loading of enzymatic hydrolysis was increased to 25% solid loading, the same pulp 16

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(pretreated at 20%) even gave a 1% higher sugar yields (86.2% glucose yield and 76.8%

355

xylose), releasing 241.2 g/L fermentable sugars (206.5 g/L glucose and 34.7 g/L xylose).

356

The sugar yields were lower when switchgrass pretreated at 27% solid loading was

357

enzymatically hydrolyzed. However, the glucose yield of 82% and xylose yield of 69.9%

358

were still obtainable at 20% solid loading enzymatic hydrolysis, which corresponded to a

359

glucose and xylose concentration of 146.5 and 26.8 g/L, respectively (Fig.4). When the

360

enzymatic hydrolysis was conducted at a 25% solid loading, the total fermentable sugars

361

reached 190 g/L (159.5 g/L glucose and 31.4 g/L xylose. Overall, both pulp samples were

362

suitable for concentrated hydrolysis production while the one resulting from 20% solid

363

loading pretreatment was more digestible at high-solid loading enzymatic hydrolysis. More

364

concentrated sugar production would be expected upon enzymatic hydrolysis optimization.

365

Some recently developed novel pretreatments, such as DMR (deacetylation and

366

mechanical refining) and γ-irradiation pretreatment, were also reported to enable

367

concentrated sugar hydrolysate production from lignocellulosic biomass.5, 34 At solid

368

loadings of 28% and 25%, DMR-pretreated corn stover and γ-irradiation-pretreated reed

369

stover gave 230 and 231 g/L monomeric sugar concentrations, respectively.5, 34 With similar

370

solid loadings for enzymatic hydrolysis the pulp resulting from our proposed DES

371

pretreatment was able to release comparable or even larger amounts of total monomeric

372

sugars (241.2 g/L corresponding to a glucose yield of 86.2%). Such impressive

373

saccharification results indicated that aqueous ChCl:EG pretreatment developed in this

374

study is a highly promising pretreatment technology to enable concentrated sugar

375

production, which would be of great significance to biorefinery industry. 17

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376

2,3-BD production from concentrated sugar hydrolysate. Concentrated sugar

377

hydrolysate directly resulting from high solid loading enzymatic hydrolysis would be a

378

suitable substrate for high titer biofuel or chemical production. We tested two hydrolysates

379

as presented in Fig.4 for 2,3-BD production via batch fermentation: P20/EH20 and

380

P20/EH25. The initial total sugar concentrations in the fermentation media were adjusted to

381

174.5 g/L (with 152.0 g/L glucose and 22.5 g/L xylose) and 226.3 g/L (with 193.7g/L

382

glucose and 32.6 g/L xylose), respectively, since adding the stock solution of nutrients and

383

pH adjustment slightly diluted the hydrolysate. For the initial sugar (glucose and xylose)

384

concentration of 174.5 g/L, glucose was depleted within 36 h by B. vallismortis (NRRL

385

B-14891), and 68.50 g/L 2,3-BD was produced, corresponding to a productivity of 1.90

386

g/L-h and a yield of 88.5% (Fig.5a). In contrast, xylose was almost not converted until

387

depletion of glucose, implying carbon catabolite repression in 2,3-BD fermentation by B.

388

vallismortis. When the higher initial sugar concentration (226.3 g/L) was tested, glucose

389

was completely depleted along with gradual consumption of xylose (only 18.4% consumed

390

in total) within 72 fermentation, resulting in a 2,3-BD titer of 90.2 g/L with a productivity

391

of 1.25 g/L-h and a yield of 89.6% (based on total sugar consumption) (Fig.5b). The results

392

suggested that B. vallismortis could not utilize xylose well in mixed C5 and C6 sugars

393

toward 2,3-BD production. If only considering glucose consumption, the yield of 2,3-BD

394

was as high as 93.0%. Based on mass balance analysis, 152 g of 2,3-BD can be produced

395

per 1000 g raw switchgrass (Fig.6).

396 397

Research efforts in strain development have improved the abilities of 2,3-BD producing strains for the utilization of glucose and xylose.6 However, the challenges with 18

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direct production of concentrated lignocellulosic hydrolysate largely limits economically

399

viable production of 2,3-BD from lignocellulosic biomass. Due to low to moderate sugar

400

concentrations in lignocellulosic hydrolysate, 2,3-BD titer ranged from about 10 g/L to a

401

maximum of 55.7 g/L in previous studies.7, 35-36 To the best of our knowledge, we reported

402

for the first time more industrially relevant 2,3-BD production with the highest 2,3-BD

403

TYP based on lignocellulosic biomass hydrolysate without additional concentration and

404

detoxification. In the future study we will test more concentrated hydrolysates, different

405

fermentation modes (e.g., fed-batch), and xylose-utilizing strains, to further improve

406

2,3-BD TPY toward commercial level production.

407

Lignin fate. As mentioned previously, acidified ChCl:EG pretreatment rendered

408

significant removal of xylan and lignin and generated a highly digestible cellulose-rich

409

pulp (Figs.2a&S4). To understand the mechanism of the pretreatment and lignin properties,

410

lignin purity and chemistry were examined. Compared with lignin generated from 20%

411

solid loading pretreatment, lignin from 27% solid loading showed a lower purity. At 20%

412

solid loading, when water content in acidified ChCl:EG increased from 0% to 20%, lignin

413

purity increased from 83% to 86% (Table 1). A similar trend was also observed with 27%

414

solid loading pretreatment, suggesting a positive effect of water addition on the lignin

415

purity. A previous study suggested that EG can react with lignin by forming esters and

416

ketals, and the reaction is influenced by both acid concentration and water content.37

417

Plausibly, under higher water content (e.g., 20%), EG was less reactive with lignin. This

418

was supported by the compositional analysis results, which revealed that the lignin

419

obtained from aqueous ChCl:EG containing 20% water had the lowest EG content, and 19

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420

therefore the highest purity (Table 1). In addition, ChCl can also react with lignin,38 and a

421

higher water content may lower the reaction rate due to the interaction of ChCl with water.

422

Overall, water influences the lignin purity by affecting the reaction between ChCl:EG and

423

extracted lignin. In terms of lignin yield, more than 50% of solubilized lignin could be

424

recovered at 20% solid loading using either neat or acidified, aqueous ChCl:EG. As

425

reported by a previous study, the aqueous DESs can dissolve lignin , and therefore, the

426

lignin extracted into ChCl:EG could not be completely recovered via precipitation.39

427

Increasing the amount of water to enhance lignin precipitation or using membrane filtration

428

may help improve the lignin recovery.32 Increasing solid loading to 27% led to decreased

429

lignin removal and recovery but had minor effects on lignin purity (Table 1). With solvent

430

recycling, lignin purity remained at 80-82% while cumulative lignin yield was increased

431

from 52% to 79% (Table 2). It is worthy of investigating the mechanism for increased

432

lignin yield and possible formation of pseudo-lignin upon solvent recycling in the future

433

study.

434

To understand the change in lignin chemistry, lignin from 20% and 27% solid loading

435

pretreatment using acidified, aqueous ChCl:EG containing 10% water, denoted as L20 and

436

L27, respectively, were examined using 2D HSQC NMR. Main 13C-1H cross-signals in the

437

HSQC spectra of switchgrass lignin were assigned according to previous studies

438

(Fig.7).40-41 The presence of β-O-4 substructure (A) in native lignin was detected by the

439

cross peaks at δC/ δH 71.84/4.86 (Aα), 83.68/4.29 (Aβ) and 60.00/3.60 (Aγ) (Fig.7).

440

However, in L20 and L27, the contours for β-O-4 linkages shrank. Semi-quantification

441

revealed the percentages of β-O-4 linkage in L20 and L27 were 1.53% and 4.98%, 20

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442

respectively, as compared to 46.72% in native switchgrass lignin (Table S1). Acidified

443

ChCl:EG may work similarly as ChCl:lactic acid (LA), which cleaves β-O-4 in lignin to

444

facilitate lignin solubilization.38 Taken together, these results indicated the important role of

445

acidic proton in DES pretreatment. Previous studies suggested that the preservation of

446

β-O-4 linkages is critical for monomer production via catalytic depolymerization.42

447

Therefore, L20 may not be suitable for the production of aromatics via depolymerization.

448

However, the elimination of ether bonds may render lignin with better polymer stability.

449

Taking into account its relatively high purity, such lignin may serve as good building

450

blocks for the synthesis of advanced materials. Differing from L20, L27 preserved some of

451

the ether bonds during pretreatment (Fig.7), implying that by adjusting the pretreatment

452

conditions (e.g., solid loading, pretreatment time) during acidified ChCl:EG pretreatment,

453

lignin with different structures (e.g., varying molecular weight, different abundance of

454

β-O-4 linkage) can be obtained.

455

The dominant peaks shown in aromatic regions were syringyl (S), guaiacyl (G),

456

p-coumarate (p-CA), and ferulate (FA). The apparent difference in the aromatic region

457

between native lignin and DES lignin was the decreased peak intensity for FA and p-CA in

458

L20 and L27. As shown in Table S1, the relative percentages of FA in L20 and L27 were

459

4.98 and 5.46%, respectively, while 9.35% in native lignin. Similarly, the relative

460

percentages of p-CA in DES lignin were also lower than that in native lignin. In grass

461

lignin, both p-CA and FA acylate arabinoxylans, and serve as the bridge between lignin and

462

polysaccharide via formation of ether and ester linkages.43 The decreased relative

463

percentage of p-CA and FA suggested the cleavage of lignin-polysaccharide during 21

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464 465

pretreatment, which facilitated the isolation of lignin and xylan from switchgrass. The GPC results of L20 and L27 compared to that of native lignin are given in Table 3.

466

The average molecular weight (Mw) of native lignin was 9544 g/mol, attributed to the

467

macropolymer structure of native lignin. The Mw decreased in both L20 and L27,

468

confirming that lignin partly depolymerizes during the ChCl:EG pretreatment. The

469

polydispersity (PD) also decreased with the ChCl:EG derived lignin for narrower molecular

470

distribution. The average Mw and PD were both lower with L20 compared to L27 (3933

471

g/mol vs. 4600 g/mol, and 3.34 vs. 3.75), which imply that lignin decomposes more

472

severely during the pretreatment with 20% solid loading. As previously shown in Fig.6,

473

ether bond cleavage was less significant in the case of 27% solid loading pretreatment, thus

474

producing a less depolymerized lignin.

475

Thermal stability of lignin was determined based on the TGA results shown in Fig.S6.

476

Compared to native lignin, L20 and L27 both decomposed at higher temperatures. Since

477

the weak aryl ether bonds were partly cleaved during ChCl:EG pretreatment, the bonds

478

remaining in the recovered lignin are thermally more stable. L20 had a higher thermal

479

stability than L27 to produce a higher amount of solid residue upon pyrolysis despite its

480

lower Mw and PD. In addition to ether bond cleavage, secondary reactions likely occurred

481

during the DES pretreatment. The reactive free radicals generated from the primary

482

depolymerization of lignin could couple each other to form a new molecular structure with

483

thermally more stable bonds (e.g., intra aromatic C-C bonds). Since lignin is

484

depolymerized more severely with a lower solid loading pretreatment, it is expected that

485

secondary reactions during the pretreatment were also more pronounced with L20. In 22

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486

comparison, L27 better preserved aryl ether bonds and some other weak bonds, and thus

487

had higher volatility. Higher volatility is usually desired in order to upgrade the lignin for

488

biofuels and chemicals. On the other hand, higher thermal stability and narrower Mw

489

distribution are preferred if the lignin is to be used as biocarbon materials, such as carbon

490

fiber.

491

Lignin is known as an important source of renewable aromatics. For instance,

492

lignin-derived phenolic monomers are valuable chemicals that have wide applications.

493

Thus, ChCl:EG lignin were also pyrolyzed for phenolic monomers and the results were

494

compared with that from native lignin (Table S2). Due to herbaceous nature of switchgrass

495

and demethoxylation during pyrolysis, H type phenols were most abundant among the

496

monomers, followed by G type and S type of monomers at all three kinds of lignin. Also,

497

4-vinylphenol and 4-vinyl guaiacol were the two major monomers, which were mainly

498

produced from decomposition of hydroxycinnamate groups and β-O-4 cleavages.20

499

Pyrolysis of native lignin delivered the highest total monomer yield, which was 14.58%. In

500

comparison, the yields were 8.03% from L20 and 9.08% from L27 due to the decreased

501

contents of ether linkages and increased thermal resistivity of ChCl:EG lignin for

502

volatilization. However, simpler and short-side chain phenols, such as phenol, guaiacol,

503

cresol, methyguaiacol, and ethylphenol, were more selectively produced from L20 and L27

504

compared to native lignin since the aromatic side chains were partially cleaved during the

505

ChCl:EG pretreatment. L27 produced more monomers than L20, which well corresponded

506

to the less modified lignin structure and higher volatility of L27 compared to L20.

507

Especially, higher yield of 4-vinylphenol was obtained with L27 because it contained more 23

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508 509

β-O-4 linkages. Summarizing the characterization results described above, it can be concluded that the

510

ChCl:EG lignin is comparable to switchgrass lignin extracted otherwise,40-41 and higher

511

solid loading pretreatment actually improved the quality of the resulting lignin in terms of

512

volatilization and upgrading for phenolic monomers.

513

Pretreatment liquor upgrading for furfural production. As discussed above,

514

ChCl:EG pretreatment can efficiently solubilize xylan under acidic condition, leading to up

515

to 75.6% xylan removal at high-solid pretreatment. Without solvent recycling, xylan-based

516

sugars in the liquor accounted for up to 94% xylan removed during the pretreatment, most

517

of which was presented in a form of xylo-oligosaccharide (XOS) (Table S3). In contrast,

518

solvent recycling led to 70.0% xylan removal from switchgrass, but only 56.8% xylan

519

recovery in the pretreatment liquor. Reduced xylan recovery in the recycled liquor implied

520

obvious degradation of xylan-based sugars upon solvent recycling while no furfural was

521

detected in any pretreatment liquor. Nonetheless, solvent recycling had many benefits as

522

aforementioned. One was highly enriched xylan-based sugars in the pretreatment liquor,

523

reaching 78.7 g/L XOS and 14.52 g/L xylose (Fig.8), which can facilitate further upgrading

524

of pretreatment liquor.

525

Since many ChCl-based DESs appear to be suitable reaction media for xylan/xylose to

526

furfural, we further upgraded the pretreatment liquor to furfural by taking advantage of

527

such a ChCl:EG-based liquor as both reaction medium and substrate.44 This was also the

528

first study to use ChCl:EG as a reaction medium for furfural production. Since AlCl3 has

529

been shown to accelerate ChCl-based DESs, its loading was first optimized using aqueous 24

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530

ChCl:EG (50 wt%) containing 100 g/L pure xylose. As shown in Fig.S7, the furfural yield

531

leveled off when 1.5 (w/v)% AlCl3 was loaded, reaching 90% overall yield. Also in

532

agreement with prior studies,44 water instead of DES as a reaction medium showed a 34%

533

lower furfural yield, suggesting strong synergism between ChCl:EG and AlCl3 in

534

converting xylose to furfural.

535

Applying 1.5% AlCl3 to liquor upgrading, we found that similar overall furfural yields

536

(91-92%) were obtained with unrecycled liquor (Table S3). Recycled liquor gave a reduced,

537

but still outstanding overall furfural yield (84.52%). It was possible that repeatedly

538

recycled liquor may contain more impurities, which in turn affected xylose conversion into

539

furfural. Nonetheless, recycled liquor gave a high furfural titer since it was enriched with

540

xylan-based sugars. Furfural was detected at 12.95 g/L in MIBK and its partition

541

coefficient for MIBK/aqueous was 2.8 (Fig.8). Correspondingly, the MIBK phase

542

contained 92% of the produced furfural, and can be easily separated from aqueous phase

543

due to its immiscibility with aqueous ChCl:EG.45 MIBK can be recovered from the organic

544

phase via distillation since it has a relatively low boiling point. The aqueous phase, which

545

mainly contained ChCl, EG, and water but no xylan-based sugars, can be recycled by

546

removing water as needed. However, based on total xylan removal, solvent recycling gave

547

a much lower furfural output than no solvent recycling (Table S3). On a basis of 1000 g

548

raw switchgrass was 57.0 g furfural produced for solvent recycling vs. about 101 g furfural

549

for no solvent recycling (Table S3&Fig.6). Therefore, research efforts should be invested in

550

the future study to minimize xylan degradation upon solvent recycling and condition

551

recycled liquor as needed for pretreatment liquor upgrading. 25

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552 553

CONCLUSIONS High solid loading, aqueous ChCl:EG-based pretreatments were highly efficient under

554

acidic condition for lignin and xylan removal, rendering a cellulose-rich residue with high

555

digestibility for concentrated sugar production. Within only 48 h of 25% solid-loading

556

enzymatic hydrolysis, the pulp pretreated at 20% solids was hydrolyzed into 241.2 g/L

557

fermentable sugars (206.5 g/L glucose and 34.7 g/L xylose) with a glucose yield over 85%.

558

Such hydrolysate allowed 2,3-BD production with a titer as high as 90.2 g/L without

559

additional sugar concentration for the first time. The pulp pretreated at 27% solids can also

560

be enzymatically hydrolyzed at high solids although a lesser amount of sugars was released.

561

On the other hand, the lignin extracted at 27% solid loading pretreatment was less

562

depolymerized, thus having better thermal volatility and producing a higher yield of

563

phenolic monomers upon pyrolysis. ChCl:EG was successfully recycled and reused for at

564

least three pretreatment cycles. Recycling ChCl:EG for pretreatment improved the

565

accumulative lignin yield while not affecting the lignin purity. Solvent recycling also

566

enriched xylan-rich sugars in the liquor, which can be used as both reaction medium and

567

substrate for furfural production. This study developed a high solid loading pretreatment

568

using high performance, recyclable aqueous ChCl:EG, which enabled industrially relevant

569

production of sugar hydrolysates and platform chemicals.

570

ASSOCIATED CONTENT

571

Supporting Information. Experimental sections; Semi-quantification of the β-O-4

572

and hydroxylcinnamates abundance in lignin; Yields of phenolic monomers produced from

573

lignin pyrolysis; Xylan removal and recovery in pretreatment liquor for furfural production; 26

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Switchgrass major component distribution and solid recovery in response to different

575

pretreatment solvents and conditions; XRD patterns and FTIR spectra of the pretreated

576

switchgrass; TGA profiles of DES lignin; Effect of AlCl3 addition on pure xylose

577

conversion into furfural in ChCl:EG DES.

578

CONFLICTS OF INTEREST

579

There are no conflicts to declare.

580

ACKNOWLEDGEMENTS

581

The authors wish to thank the support from the University of Missouri Research Board and

582

NMR core facility.

583 584

REFERENCES

585 586 587 588 589 590 591 592 593 594 595 596 597 598 599 600 601 602 603 604 605 606

(1) Chen, Z.; Reznicek, W. D.; Wan, C. Deep eutectic solvent pretreatment enabling full utilization of switchgrass. Bioresour. Technol. 2018, 263, 40-48. (2) Sun, S.; Sun, S.; Cao, X.; Sun, R. The role of pretreatment in improving the enzymatic hydrolysis of lignocellulosic materials. Bioresour. Technol. 2016, 199, 49-58. (3) Modenbach, A. A.; Nokes, S. E. The use of high—solids loadings in biomass pretreatment—a review. Biotechnol. Bioeng. 2012, 109 (6), 1430-1442. (4) Nguyen, T. Y.; Cai, C. M.; Osman, O.; Kumar, R.; Wyman, C. E. CELF pretreatment of corn stover boosts ethanol titers and yields from high solids SSF with low enzyme loadings. Green Chem. 2016, 18 (6), 1581-1589. (5) Chen, X.; Kuhn, E.; Jennings, E. W.; Nelson, R.; Tao, L.; Zhang, M.; Tucker, M. P. DMR (deacetylation and mechanical refining) processing of corn stover achieves high monomeric sugar concentrations (230 g L− 1) during enzymatic hydrolysis and high ethanol concentrations (> 10% v/v) during fermentation without hydrolysate purification or concentration. Energy Environ. Sci. 2016, 9 (4), 1237-1245. (6) Ji, X.-J.; Huang, H.; Ouyang, P.-K. Microbial 2, 3-butanediol production: a state-of-the-art review. Biotechnol. Adv. 2011, 29 (3), 351-364. (7) Adlakha, N.; Yazdani, S. S. Efficient production of (R, R)-2, 3-butanediol from cellulosic hydrolysate using Paenibacilluspolymyxa ICGEB2008. J. Ind. Microbiol. Biotechnol. 2015, 42 (1), 21-28. (8) Um, J.; Kim, D. G.; Jung, M.-Y.; Saratale, G. D.; Oh, M.-K. Metabolic engineering of Enterobacter aerogenes for 2, 3-butanediol production from sugarcane bagasse hydrolysate. Bioresour. Technol. 2017, 245, 1567-1574. (9) Ramachandriya, K. D.; Wilkins, M.; Atiyeh, H. K.; Dunford, N. T.; Hiziroglu, S. Effect of high dry solids loading on enzymatic hydrolysis of acid bisulfite pretreated Eastern redcedar. Bioresour. Technol. 2013, 27

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of rice straw via a high-performance two-stage deep eutectic solvents synergistic pretreatment. Bioresour. Technol. 2017, 238, 139-146. (29) Kumar, A. K.; Parikh, B. S.; Pravakar, M. Natural deep eutectic solvent mediated pretreatment of rice straw: bioanalytical characterization of lignin extract and enzymatic hydrolysis of pretreated biomass residue. Environ. Sci. Pollut. Res. 2016, 23 (10), 9265-9275. (30) Li, C.; Knierim, B.; Manisseri, C.; Arora, R.; Scheller, H. V.; Auer, M.; Vogel, K. P.; Simmons, B. A.; Singh, S. Comparison of dilute acid and ionic liquid pretreatment of switchgrass: biomass recalcitrance, delignification and enzymatic saccharification. Bioresour. Technol. 2010, 101 (13), 4900-4906. (31) Karp, E. M.; Resch, M. G.; Donohoe, B. S.; Ciesielski, P. N.; O’Brien, M. H.; Nill, J. E.; Mittal, A.; Biddy, M. J.; Beckham, G. T. Alkaline pretreatment of switchgrass. ACS Sustainable Chem. Eng. 2015, 3 (7), 1479-1491. (32) Kim, K. H.; Dutta, T.; Sun, J.; Simmons, B.; Singh, S. Biomass pretreatment using deep eutectic solvents from lignin derived phenols. Green Chem. 2018, 20 (4), 809-815. (33) Narron, R. H.; Chang, H.-m.; Jameel, H.; Park, S. Soluble Lignin Recovered from Biorefinery Pretreatment Hydrolyzate Characterized by Lignin–Carbohydrate Complexes. ACS Sustainable Chem. Eng. 2017, 5 (11), 10763-10771. (34) Zhou, H.; Zhang, R.; Zhan, W.; Wang, L.; Guo, L.; Liu, Y. High biomass loadings of 40 wt% for efficient fractionation in biorefineries with an aqueous solvent system without adding adscititious catalyst. Green Chem. 2016, 18 (22), 6108-6114. (35) Ling, H.; Cheng, K.; Ge, J.; Ping, W. Corncob Mild Alkaline Pretreatment for High 2,3-Butanediol Production by Spent Liquor Recycle Process. Bioenergy Res. 2017, 10 (2), 566-574. (36) Saratale, R. G.; Shin, H. S.; Ghodake, G. S.; Kumar, G.; Oh, M. K.; Saratale, G. D. Combined effect of inorganic salts with calcium peroxide pretreatment for kenaf core biomass and their utilization for 2, 3-butanediol production. Bioresour. Technol. 2018, 258, 26-32. (37) Moghaddam, L.; Zhang, Z.; Wellard, R. M.; Bartley, J. P.; O'Hara, I. M.; Doherty, W. O. Characterisation of lignins isolated from sugarcane bagasse pretreated with acidified ethylene glycol and ionic liquids. Biomass Bioenergy 2014, 70, 498-512. (38) Alvarez-Vasco, C.; Ma, R.; Quintero, M.; Guo, M.; Geleynse, S.; Ramasamy, K. K.; Wolcott, M.; Zhang, X. Unique low-molecular-weight lignin with high purity extracted from wood by deep eutectic solvents (DES): a source of lignin for valorization. Green Chem. 2016, 18 (19), 5133-5141. (39) Soares, B.; Tavares, D. J.; Amaral, J. L.; Silvestre, A. J.; Freire, C. S.; Coutinho, J. o. A. Enhanced solubility of lignin monomeric model compounds and technical lignins in aqueous solutions of deep eutectic solvents. ACS Sustainable Chem. Eng. 2017, 5 (5), 4056-4065. (40) Samuel, R.; Pu, Y.; Raman, B.; Ragauskas, A. J. Structural characterization and comparison of switchgrass ball-milled lignin before and after dilute acid pretreatment. Appl. Biochem. Biotechnol. 2010, 162 (1), 62-74. (41) Samuel, R.; Foston, M.; Jiang, N.; Allison, L.; Ragauskas, A. J. Structural changes in switchgrass lignin and hemicelluloses during pretreatments by NMR analysis. Polym. Degrad. Stab. 2011, 96 (11), 2002-2009. (42) Renders, T.; Van den Bosch, S.; Koelewijn, S.-F.; Schutyser, W.; Sels, B. Lignin-first biomass fractionation: the advent of active stabilisation strategies. Energy Environ. Sci. 2017, 10 (7), 1551-1557. (43) Kim, H.; Ralph, J. Solution-state 2D NMR of ball-milled plant cell wall gels in DMSO-d6/pyridine-d5. Org. Biomol. Chem. 2010, 8 (3), 576-591. (44) Zhang, L.-X.; Yu, H.; Yu, H.-B.; Chen, Z.; Yang, L. Conversion of xylose and xylan into furfural in biorenewable choline chloride–oxalic acid deep eutectic solvent with the addition of metal chloride. Chin. 29

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Chem. Lett. 2014, 25 (8), 1132-1136. (45) Di Marino, D.; Aniko, V.; Stocco, A.; Kriescher, S.; Wessling, M. Emulsion electro-oxidation of kraft lignin. Green Chem. 2017, 19 (20), 4778-4784.

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Figure captions

700 701 702 703 704 705 706 707 708 709 710 711 712 713 714 715 716 717 718 719 720 721 722 723 724 725 726 727 728 729 730 731 732 733 734 735 736 737

Fig.1. Switchgrass component removal and digestibility in response to the pretreatment using different solvents. (a) Major component removal, and (b) Switchgrass digestibility. Fig.2. Switchgrass component removal and digestibility in response to ChCl:EG pretreatment under acidic condition with varying water addition and solid loadings. (a) Major component removal, and (b) Switchgrass digestibility. W0, W10, and W20 stand for 0, 10%, and 20% water content in ChCl:EG, respectively. Fig.3. Switchgrass component removal and digestibility in response to different pretreatment cycles under acidic condition using aqueous ChCl:EG with 10% water and at 27% solid loading. (a) Major component removal, and (b) Switchgrass digestibility. Fig.4. High-solid loading enzymatic hydrolysis of switchgrass pretreated at high solids using acidified, aqueous ChCl:EG with 10% water. P20 and P27 stand for 20% and 27% solid loadings for pretreatment. EH20 and EH25 stand for 20% and 25% solid loading enzymatic hydrolysis of pretreated solids. The enzymatic hydrolysis lasted for 48 h. Fig.5. Fermentative production of 2,3-BD from switchgrass hydrolysate. Two types of hydrolysate presented in Fig.4 were tested: (a) P20/EH20, and (b) P20/EH25. In every 20 mL fermentation medium, 18.5 mL of P20/EH20 or 18.8 mL of P20/EH25 was added to obtain the initial sugar concentrations as presented. Fig.6. Mass flow analysis of the proposed biorefinery based on high-solid loading DES pretreatment for lignocellulose conversion into platform chemicals. The solvent was acidified, aqueous ChCl:EG with 10% water addition. The mass flow analysis was based on a single high-solid pretreatment cycle. Lignin-rich residue was estimated as the amount of residue remaining after sugar release. P20: 20% solid-loading pretreatment. EH 25: 25% solid-loading enzymatic hydrolysis for 48h. F194: batch-fermentation with initial glucose concentration of 194 g/L. XOS: xylo-oligosaccharides. 2,3-BD yield in parenthesis was calculated based on glucose consumption only. Fig.7. 2D HSQC NMR analysis of DES lignin. L20 and L27 stand for lignin recovered from 20% and 27% solid-loading pretreatment, respectively, using acidified, aqueous ChCl:EG with 10% water addition. Note that some correlations were invisible at the contour level plotted, but were still visible at lower contour level. “Aγ+?” represents correlation of Aγ and unassigned contour.

Fig.8. Furfural production from the pretreatment liquor. Xylose was present in the pretreatment liquor in the forms of monomer and xylo-oligosaccharide (XOS) (72.43 g/L equivalent to 82.31g/L of xylose as presented). The pretreatment liquor tested was collected at the 4th 27% solid-loading pretreatment cycle with solvent recycling.

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Table 1. Lignin removal and recovery in response to high-solid loading DES pretreatment with a varying water content *

738 739

Solid loading of pretreatment 20%

27%

740

*

741

a

742

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Water content in ChCl:EG a W0 W10 W20 W0 W10 W20

Lignin removal (%) 78.90±2.10 79.39±0.15 79.45±0.44 74.55±0.77 74.41±0.12 69.41±1.29

Lignin yield (%) 53.23±2.15 57.63±2.61 52.98±2.31 44.95±1.30 51.77±2.44 49.76±1.24

EG b (%) 6.59±0.30 6.39±0.30 5.59±0.28 6.26±0.24 6.24±0.14 5.72±0.13

Lignin purity (%) 83.34±0.28 85.85±0.82 86.14±0.32 82.40±0.55 83.16±0.15 84.96±0.37

ChCl:EG pretreatment under acidic condition W0, W10, and W20 stands for water addition at 0%, 10%, and 10%, respectively. b Data reported for EG content in DES lignin

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Table 2. Lignin removal and recovery in response to pretreatment solvent recycling* Pretreatment cycle 1 2 3 4

744

*

745

a

Lignin removal (%) 74.41±0.12 70.10±1.83 72.00±0.25 60.89±1.83

Cumulative Lignin lignin yield (%) a purity (%) 83.16±0.15 51.77±2.44 63.71±2.89 82.10±0.43 66.34±1.84 82.65±0.53 79.24±3.40 80.36±0.39

27% solid pretreatment using acidified, aqueous ChCl:EG with 10% water Cumulative lignin yield calculated based on cumulative pretreatment cycles

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746

Table 3. Average molecular weight and polydispersity (PD) of DES lignin* Samples Native lignin L20 L27

747 748

Mn 1951 1176 1229

Mw 9544.5 3932.5 4599.5

*

PD 4.89 3.34 3.75

L20 and L27 stand for lignin recovered from 20% and 27% solid-loading pretreatment, respectively, under acidic condition using aqueous ChCl:EG with 10% water addition.

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(a)

100

Glucan

Xylan

Lignin

90

Component removal (%)

80 70 60 50 40 30 20 10 0

Ch

749

%H +1.0 Cl:EG

2SO

4

1 .0 EG+

S O4 %H 2

l:EG ChC

1 .0 %

H2SO

4

750 (b) 110

Glucose

100

Xylose

90 80

Sugar yield (%)

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

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70 60 50 40 30 20 10 0

Untre

751 752 753 754

a te d C

0 G+1. hCl:E

%H2

SO4

1. EG+

0% H

2SO

4

l:EG ChC

1.0%

4 H2SO

Fig.1. Switchgrass component removal and digestibility in response to the pretreatment using different solvents. (a) Major component removal, and (b) Switchgrass digestibility.

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(a)

100

G lucan

X yla n

L ignin

90

Component removal (%)

80 70 60 50 40 30 20 10 0

W0

756 757 758

(b)

763 764 765 766

W 20

W0

W 10

W 20

27 % S olid loading

Glucan

100

Xylan

90

759 760 761 762

W 10

20% S olid load ing

755

80

Sugar yield (%)

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

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70 60 50 40 30

767 768 769 770 771 772 773 774 775 776 777

20 10 0

W0

W10

W20

W0

20% Solid loading

W10

W20

27% Solid loading

Fig.2. Switchgrass component removal and digestibility in response to ChCl:EG pretreatment under acidic condition with varying water addition and solid loadings. (a) Major component removal, and (b) Switchgrass digestibility. W0, W10, and W20 stand for 0, 10%, and 20% water content in ChCl:EG, respectively.

778

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(a)

100

Glucan

Xylan

Lignin

90

Component removal (%)

80 70 60 50 40 30 20 10 0 1

2

3

4

Pretreatm ent cycle

779

(b) Glucose

100

Xylose

90 80

Sugar yield (%)

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

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70 60 50 40 30 20 10 0 1

780 781 782 783

2

3

4

Pretreatment cycle

Fig.3. Switchgrass component removal and digestibility in response to different pretreatment cycles under acidic condition using aqueous ChCl:EG with 10% water and at 27% solid loading. (a) Major component removal, and (b) Switchgrass digestibility.

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280 260

100

Glucose Con. Xylose Con. 241.2 g/L

Glucose yield Xylose yield

90

220

80

200

70

180 60 160 140

50

120

40

Sugar yield (%)

240

Sugar concentration(g/L)

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

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100 80

30

60

20

40 10 20 0

784 785 786 787 788

P20 EH20

P20 EH25

P27 EH20

P27 E25

0

Fig.4. High-solid loading enzymatic hydrolysis of switchgrass pretreated at high solids using acidified, aqueous ChCl:EG with 10% water. P20 and P27 stand for 20% and 27% solid loadings for pretreatment. EH20 and EH25 stand for 20% and 25% solid loading enzymatic hydrolysis of pretreated solids. The enzymatic hydrolysis lasted for 48 h.

789

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(a) Glucose Xylose 2,3-BD

Glucose and xylose (g/L)

140

70 60

120

50

100

40

80

30

60

20

40

10

20

0

0

-10 0

10

20

30

40

50

60

Time (h)

790 791 (b) 220

100

Glucose Xylose 2,3-BD

200 180

90 80

160

60 120 50 100 40 80 30

60

20 10

20 0

0 0

793 794 795 796

2,3-BD (g/L)

70

140

40

792

2,3-BD (g/L)

160

Glucose and xylose (g/L)

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

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12

24

36

48

60

72

Time (h)

Fig.5. Fermentative production of 2,3-BD from switchgrass hydrolysate. Two types of hydrolysate presented in Fig.4 were tested: (a) P20/EH20, and (b) P20/EH25. In every 20 mL fermentation medium, 18.5 mL of P20/EH20 or 18.8 mL of P20/EH25 was added to obtain the initial sugar concentrations as presented.

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797 798 799 800 801 802 803 804 805 806 807 808 809 810 811 812 813 814 815 816 817 818 819 820 821

Fig.6. Mass flow analysis of the proposed biorefinery based on high-solid loading DES pretreatment for lignocellulose conversion into platform chemicals. The solvent was acidified, aqueous ChCl:EG with 10% water addition. The mass flow analysis was based on a single high-solid pretreatment cycle. Lignin-rich residue was estimated as the amount of residue remaining after sugar release. P20: 20% solid-loading pretreatment. EH 25: 25% solid-loading enzymatic hydrolysis for 48h. F194: batch-fermentation with initial glucose concentration of 194 g/L. XOS: xylo-oligosaccharides. 2,3-BD yield in parenthesis was calculated based on glucose consumption only.

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822

823 824 825 826

Fig.7. 2D HSQC NMR analysis of DES lignin. L20 and L27 stand for lignin recovered from 20% and 27% solid-loading pretreatment, respectively, using acidified, aqueous ChCl:EG with 10% water addition. Note that some correlations were invisible at the contour level plotted, but were visible at lower contour level. “Aγ+?” represents the correlation of Aγ and unassigned contour.

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827 100

120 110

XOS Xylose

Yield (MIBK) Yield (aqueous)

Titer (MIBK) Titer (aqueous)

14 90

100 80

12

70

80 70

Liquor

Furfural

60

60

50

50

40

10

8

6

Furfural titer (g/L)

90

Furfural yield (%)

Xylose concentration in the pretreatment liquor (g/L)

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

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40 30

4

30 20

20

2 10

10 0

0

0

828 829 830 831 832

Fig.8. Furfural production from the pretreatment liquor. Xylose was present in the pretreatment liquor in the forms of monomer and xylo-oligosaccharide (XOS) (72.43 g/L equivalent to 82.31g/L of xylose as presented). The pretreatment liquor tested was collected at the 4th 27% solid-loading pretreatment cycle with solvent recycling.

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ACS Sustainable Chemistry & Engineering

Synopsis: A novel deep eutectic solvent system enables high-solid lignocellulose processing for lignin extraction and industrially relevant production of platform chemicals.

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