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A Lignin-First Approach to Biorefining: Utilizing Fenton’s Reagent and Supercritical Ethanol for the Production of Phenolics and Sugars William J. Sagues, Hanxi Bao, John L Nemenyi, and Zhaohui Tong ACS Sustainable Chem. Eng., Just Accepted Manuscript • DOI: 10.1021/ acssuschemeng.7b04500 • Publication Date (Web): 13 Feb 2018 Downloaded from http://pubs.acs.org on February 15, 2018
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A Lignin-First Approach to Biorefining: Utilizing
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Fenton’s Reagent and Supercritical Ethanol for the
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Production of Phenolics and Sugars
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William J. Sagues, Hanxi Bao, John L. Nemenyi, Zhaohui Tong*
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Department of Agricultural & Biological Engineering, University of Florida, 1741 Museum Rd
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Gainesville, Florida 32611, United States
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*Corresponding Author
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[email protected] 9
KEYWORDS
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Biomass, Lignin depolymerization, Pretreatment, Phenolic monomers, Carbohydrates
11
ABSTRACT
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Selective lignin depolymerization (SLD) has emerged as a value-added method of pretreatment
13
for lignocellulosic biorefining, in which lignin is depolymerized into valuable phenolic
14
monomers prior to utilization of the hemicellulose and cellulose. Herein, we report a biomimetic
15
Fenton catalyzed SLD process, converting sweet sorghum bagasse into an organic oil that is rich
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in phenolic monomers and a solid carbohydrate that is favorable for enzymatic hydrolysis into
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sugars. Initially, the feedstock’s molecular structure was modified through iron chelation and
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free radical oxidation via Fenton’s reagent (Fe3+, H2O2 ). The lignin component of the modified
2
feedstock was then selectively depolymerized in supercritical ethanol (250°C, 6.5MPa) under
3
nitrogen to produce a phenolic oil, with a maximum yield of 75.8 wt %. Six valuable phenolic
4
monomers were detected in this oil, with a maximum cumulative yield of 19.1 wt %. The solid
5
carbohydrate obtained after the SLD process was enzymatically hydrolyzed to liberate 62.7 wt %
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and 79.9 wt % of the initial 5-carbon and 6-carbon polysaccharides within 24 hours, respectively,
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indicating the majority of the hemicellulose and cellulose were preserved during the SLD
8
process. Fenton modification not only increased the yields of phenolic monomers, particularly
9
ethyl-p-coumarate and ethyl-ferulate, but also enhanced enzymatic hydrolysis.
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INTRODUCTION
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In a traditional biochemical approach to lignocellulosic biorefining, the biomass feedstock
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undergoes a form of energy-intensive pretreatment to partially destruct the cell wall matrix
13
comprised of lignin (15-30%), hemicellulose (25-30%), and cellulose (35-50%). Then, the
14
holocellulose (hemicellulose and cellulose) is enzymatically converted into sugars, leaving lignin
15
as a waste product.1 Lignin is the most abundant renewable aromatic polymer on the planet, and
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it is of particular interest to apply lignin-derived phenolic monomers in high value applications
17
such as antioxidant supplements, UV scavenging sunscreens, anti-inflammatory medications,
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flavors, and fragrances.2,3,4 Valuable polymers can also be synthesized from lignin-derived
19
monomers, such as plastics and resins2. The majority of lignin residues are termed “technical
20
lignins”, due to the undesirable condensation reactions during pretreatment and other unit
21
operations in which naturally present carbon-oxygen bonds (C-O) are cleaved, followed by rapid
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carbon-carbon (C-C) bond formation. Technical lignins are difficult to depolymerize due to the
23
high abundance of C-C bonds, which have a higher bond-dissociation energy than C-O bonds.5,6
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There exist many methods for depolymerization of various technical lignins using organic
2
solvents, such as methanol and ethanol, with or without catalysts, and at temperatures ranging
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from 200 – 380 °C.7,8,9,10,11 However, there are relatively few methods that selectively
4
depolymerize native lignin from intact biomass. The selective lignin depolymerization (SLD)
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method, also termed as early-stage catalytic conversion of lignin (ECCL), is a “lignin-first”
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approach to biorefining in which lignin is selectively depolymerized into valuable phenolic
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monomers as a first step, without degrading the holocellulose.5 Zhai et al. (2017) developed a
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SLD process that obtained a 39.5 wt % yield (relative to initial lignin content) of phenolic
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monomers from birch using a bimetallic Ni-Fe/activated carbon catalyst in the presence of
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hydrogen (2MPa H2 at ambient temperature) and methanol at 200 °C.12 Notably, Zhai et al.’s
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process obtained a significantly lower yield (20.3 wt %) when using organosolv lignin instead of
12
birch, demonstrating the significant advantages of the lignin-first SLD approach. Van den Bosch
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et al. (2017) demonstrated a SLD process using a Ni-Al2O3 catalyst in the presence of hydrogen
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(3MPa H2 at ambient temperature) and methanol at 250 °C to selectively depolymerize the lignin
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component of birch reaching total phenolic monomer yields of 44 wt %.13 Parsell et al. (2015)
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demonstrated a SLD process using a Zn/Pd/C catalyst in the presence of hydrogen (3.45 MPa H2
17
at ambient temperature) and methanol at 225 °C to selectively depolymerize the lignin
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component of several feedstocks into two phenolic monomers with yields ranging from 19 – 54
19
wt %.4 The aforementioned SLD processes that produced high yields of phenolic monomers
20
from whole biomass involved costly operations such as high initial pressures of hydrogen gas,
21
rare metal catalysts, or long reaction times.
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In this research, we demonstrated the ability of Fenton’s reagent (Fe3+, H2O2) to catalyze the
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selective lignin depolymerization of sweet sorghum bagasse in supercritical ethanol under an
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inert (N2) atmosphere. Fenton’s reagent has been proven to be an effective low-cost, earth-
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abundant, and biomimetic catalyst for the oxidation of organic polymers, such as lignin.11,14
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Ethanol was chosen as the solvent because it is classified as a green solvent and has beneficial
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physiochemical properties at the supercritical state.15,16 Our previous work used Fenton’s reagent
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to modify organosolv hardwood lignin prior to its depolymerization in ethanol at 250°C.11 In this
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study, we hypothesized the low-cost Fenton’s reagent coupled with supercritical ethanol could
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selectively depolymerize lignin from the intact cell wall of whole biomass through the cleavage
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of the alkyl-aryl ether β-O-4 (C-O) bond, the most prevalent bond in native lignins. Due to the
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high abundance of β-O-4 bonds in native lignins and low abundance in technical lignins, we
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expected this SLD process for whole biomass to be more effective than our previous study in
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which organosolv lignin (a technical lignin) was used. In addition, we hypothesized the SLD
12
process could preserve the holocellulose for further enzymatic hydrolysis. Sweet sorghum
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bagasse was chosen as the feedstock because it is a C4 grass that contains a high abundance of
14
esterified ferulate and p-coumarate end groups (hydroxycinnamates) in its lignin fragments.17
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Therefore, the opportunity exists for the monomerization of ferulic and p-coumaric acids and
16
related derivatives as target high value monomers for human nutrition applications.17,18 For the
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first time, a comparatively mild selective lignin depolymerization process was demonstrated in
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which Fenton’s reagent catalyzed the conversion of native lignin into low molecular weight oils
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rich in phenolic monomers, as well as the conversion of holocellulose into free 5- and 6-carbon
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sugars. The lignin-first process presented herein fills the aforementioned gaps in knowledge by
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using an inert atmosphere, earth abundant catalyst, and relatively short reaction time.
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EXPERIMENTAL
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Materials
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The sweet sorghum was grown and harvested by Agricenter LLC in Memphis, TN. After
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juicing via an industrial roller press, the bagasse was washed to remove soluble sugars and stored
3
dry. Prior to experimentation, the bagasse was sieved through mesh size 20 to ensure uniform
4
particle size. Compositional analysis of the sweet sorghum bagasse was conducted according to
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NREL’s analytical procedure (see Table S1). Iron (III) nitrate, citric acid monohydrate, and
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trisodium citrate dihydrate were purchased from Fisher. Aqueous hydrogen peroxide (35 wt %)
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and 4-vinylphenol (10 wt % in propylene glycol) were purchased from Sigma-Aldrich.
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Anhydrous ethanol was purchased from Decon Labs. 4-vinylguaiacol, isoeugenol, and ethyl
9
ferulate were purchased from Sigma-Aldrich, and ethyl-p-coumarate was purchased from Ark
10
Pharm, all in high purity. Novozyme Cellic® CTec 3 enzyme solution was generously provided
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by Novozymes®.
12
Fenton Modification (FM)
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In a general reaction, the bagasse underwent a Fenton modification (FM) in which a 50 mL
14
solution was prepared in ethanol with 2.5% biomass (w/v solution), 2.5% Fe3+ (w/w biomass),
15
and either 5 or 20% hydrogen peroxide (w/w biomass). The biomass was milled and extractives
16
were removed using the same method for biomass compositional analysis (see SI for details).
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The solution was vigorously mixed at 60 °C for 1h. For the control experiments, neither Fe3+ or
18
hydrogen peroxide was added. The Fe3+ loading was chosen to be in excess for this study since
19
the cost of hydrogen peroxide contributes significantly in techno-economic analyses of organic
20
oxidation processes that use Fenton’s reagent.14 After mixing for 1h, the solids were separated
21
from the solution via vacuum filtration, washed with deionized water, and dried.
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Selective Lignin Depolymerization (SLD)
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A 100 mL Parr reactor was used to prepare a 50 mL solution in ethanol with 2.5% Fenton
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modified biomass (w/v solution). The reactor was purged with nitrogen gas at 0.7 MPa prior to
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raising the temperature to 250°C (~ 6.5°C /min) at autogenous pressure (6.5MPa), under 700 rpm
4
agitation rate, and holding for either 0.5, 1, 3, or 12h. Upon completion, the reactor was cooled to
5
room temperature within 30 min using a custom-built air cooling device. The solids were
6
separated via vacuum filtration and washed with excess ethyl acetate, which was collected as
7
filtrate. The liquid filtrate then underwent a threefold liquid-liquid extraction using deionized
8
water to separate the organic and aqueous fractions. The organic fraction was dried with
9
magnesium sulfate prior to extended vacuum evaporation to obtain the “phenolic oil”.
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Depolymerized Lignin Characterization
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The phenolic oil yields were calculated on a mass basis using Equation 1. The lignin mass used
12
for all yield calculations refers to the initial Klason lignin content of the sweet sorghum bagasse.
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The phenolic monomers present in the phenolic oil were analyzed by gas chromatography-mass
14
spectroscopy (GC-MS, GC - Agilent 7820 and MS - Agilent 5977). Six phenolic monomers
15
present in the phenolic oil were chosen for analysis due to their relatively high concentrations
16
and valuable applications. The yields of phenolic monomers were calculated using Equation 2.
17
See Figures S1-S9 for more details regarding monomer quantification and qualification, as well
18
as statistical analyses (Table S5).
19
ℎ =
20
6 =
21
The weight average (Mw) molecular weights of the phenolic oils were determined by gel
22
permeation chromatography (GPC) on an Agilent 1260 infinity HPLC system with a refractive
23
index detector (RI-G1362A) and a multiple wavelength detector (MWD). Heteronuclear single
∑$ # "#
(1) (2)
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quantum coherence (HSQC) nuclear magnetic resonance (NMR) spectra for the phenolic oil
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were generated using a Bruker Avance II 600 MHz equipped with a 5mm TXI cryoprobe at
3
27°C.
4
Residual Holocellulose Characterization
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To characterize the holocellulose (hemicellulose and cellulose), the “solid carbohydrate”
6
retained from the SLD process underwent enzymatic hydrolysis. The enzymatic hydrolysis
7
aimed to quantify the polysaccharides available for liberation to free sugars after lignin
8
depolymerization. A 20 mL solution was prepared in citrate buffer (pH ~5.0) with 1 wt % solid
9
carbohydrate and 0.5 wt % Novozyme Cellic® CTec 3 enzyme solution. Each experiment was
10
maintained at 50 °C with moderate mixing for 24h. The 5- and 6-carbon sugars liberated during
11
enzymatic hydrolysis were quantified and then used to calculate the percentage of functional
12
holocellulose retained, as shown in Equation 3. The 5-carbon sugars that were quantified include
13
xylose and arabinose, and the 6-carbon sugars include glucose and galactose. The monomeric
14
sugars were analyzed according to our previous report24. % ℎ& '( =
15
∑#( *+# ,")(..00)1 ∑#( *2# ,")(..3.) ,
(3)
16
RESULTS & DISCUSSION
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Production of Low Molecular Weight Phenolic Oil
18
In the first step of the lignin-first process, sweet sorghum bagasse was modified via
19
Fenton’s reagent (Fe3+, H2O2) in ethanol. Fenton’s reagent involves the reaction of hydrogen
20
peroxide with transition metals (i.e. iron) or ions to generate free radicals as reactive oxidants.
21
After the modification was complete, the lignin component of the modified bagasse was
22
selectively depolymerized in supercritical ethanol under nitrogen gas to produce a low molecular
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weight phenolic oil while leaving the holocellulose as a “solid carbohydrate” (See Table S2 for
2
mass balance). The solid carbohydrate was then enzymatically converted to 5- and 6-carbon
3
sugars in high yields, indicating the previous two steps preserved the holocellulose.
4
As shown in Figure 1C, the phenolic oil yields increased with longer SLD reaction times,
5
ranging from 50.1% for 0.5h to 75.8% for 3.0h. For comparison, 12.0h SLD reactions were
6
performed, with a maximum oil yield of 84.8%, but the data for such are not discussed in detail
7
due to relatively low yields of the desired phenolic monomers and the impractical reaction time.
8
During the 12h reaction, the desired phenolic monomers generated during hours 1-3 must have
9
become degraded or repolymerized during the remaining hours 4-12. The effect FM had on
10
phenolic oil yields is evident from the increase and decrease in yields with 5 and 20% hydrogen
11
peroxide loadings, respectively, particularly for 1.0 and 3.0h SLD reactions. The phenolic oil
12
yields decreased with the 20% hydrogen peroxide loading, when compared to the 5% loading,
13
because of excessive oxidation during the FM step that led to undesirable lignin degradation. The
14
preference for a relatively low loading of hydrogen peroxide for high yields of phenolic oil
15
increases the economic feasibility of this process.
16
We propose that Fenton’s reagent performed two beneficial modifications to the
17
lignocellulosic structure, supported by our previous research (see the first reaction step in
18
Scheme 1.B). First, free radicals (e.g. •OH, •OOH) generated by Fenton’s reagent led to
19
oxidation of lignin’s pendant groups and aromatic substituents via hydroxylation and
20
demethoxylation.11 Second, an iron-lignin complex formed via chelation of iron with aromatic
21
substituents. These two structural modifications lowered the energy barrier for subsequent lignin
22
depolymerization via ß-O-4 bond cleavage. The SLD reactions presented herein did not involve
23
an acid catalyst in order to prevent the formation of reactive intermediates from degradation of
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the holocellulose and to improve the process feasibility since expensive materials are often
2
needed in acidic environments at elevated temperatures and pressures.19,20 The pH values of
3
solutions after SLD were within the range of 5.75 – 6.75, with or without FM.
4
Six valuable phenolic monomers of relatively high yield were consistently detected in the
5
phenolic oils (Figure 1A). Other monomeric products were present as well, however, they are not
6
discussed due to their low concentrations, non-phenolic structures, or the inability for accurate
7
identification. SLD reactions were performed at supercritical (250°C) and subcritical (180°C)
8
temperatures to compare yields of phenolic oil and the six phenolic monomers (Figure 1B), as
9
well as phenolic oil molecular weight (Figure 1D).
A
C 5
2
3
4
Phenolic Oil Yield (w/w Klason lignin)
1
6
B
10
80% 70% 60% 50% 40% 30% 20% 10% 0%
0.5h SLD Reaction Time
1.0h SLD Reaction Time
3.0h SLD Reaction Time
75% 60% 45% 30% 15% 0%
D
0%
5%
20%
0%
5%
20%
0%
5%
20%
Hydrogen Peroxide Loading (w/w biomass)
10000
3h, 180C 0.5h, 250C 3.0h, 250C 1.0h, 250C 12.0h, 250C
8000
Supercritical Subcritical
Intensity
Yield (w/w Klason lignin)
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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6000 4000 2000 0
Phenolic Oil
6 Phenolic Monomers
20
22
24
26
28
Time (min)
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Figure 1. (A) The six major phenolic monomers detected in the phenolic oil are as follows: 1.)
12
4-vinylphenol, 2.) 4-vinylguaiacol, 3.) trans-isoeugenol, 4.) 4-propenylsyringol, 5.) ethyl-p-
13
coumarate, and 6.) ethyl ferulate. (B) Yields of phenolic oil and the six phenolic monomers after
14
selective lignin depolymerization (SLD) at supercritical (250 °C) and subcritical (180 °C)
15
reaction temperatures. The SLD reaction time was 3h and the Fenton modification (FM)
16
hydrogen peroxide loading was 20% for both supercritical and subcritical reactions. (C) Phenolic
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oil yields obtained from SLD of sweet sorghum bagasse with varying FM hydrogen peroxide
2
loadings and reaction times. The 0% hydrogen peroxide loadings represent the control
3
experiments. (D) Gel permeation chromatogram showing the molecular weight distribution of
4
phenolic oils with varying SLD reaction times and temperatures. The phenolic oils were
5
generated using a 20% FM hydrogen peroxide loading. The peaks shifted to the right have a
6
lower average molecular weight (Mw) relative to those shifted to the left.
7
Supercritical ethanol significantly increased the yields of phenolic oil (145% increase) and the
8
six phenolic monomers (477% increase), relative to subcritical ethanol (Figure 1B). As ethanol
9
reaches the supercritical state (241°C, 6.14MPa), its polarity drops while maintaining its
10
hydrogen donating ability, and its density becomes near gas-like.16 We hypothesized these
11
physiochemical changes would improve the SLD process for several reasons. The reactivity of
12
lignin with ethanol increases at the supercritical state due to lignin’s non-polar nature, whereas
13
the reactivity of holocellulose with supercritical ethanol decreases due to the polar nature of
14
hemicellulose and cellulose. The hydrogen donating ability of ethanol at the supercritical state
15
allows for a solvolytic cleavage of the interunit bonds in lignin, primarily the ß-O-4 bonds. The
16
gas-like density of ethanol at the supercritical state dramatically increases the rate of diffusion
17
into the biomass cell wall, which subsequently increases the rate of lignin depolymerization. The
18
subcritical temperature of 180 °C was chosen for comparison because we believe this
19
temperature is well outside of the fluid structural transition zone for ethanol, and it’s a common
20
temperature used in organosolv pretreatment methods.21,22
21
The molecular weight distribution of the phenolic oils differed with varying reaction times and
22
temperatures (Figure 1D). In subcritical ethanol, the molecular weight was 1283 g/mol for the
23
3.0h SLD reaction time. In supercritical ethanol, the molecular weights of the phenolic oils
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ranged from 1085 to 668 g/mol (Mw) for 0.5 and 12h SLD reaction times, respectively. The
2
molecular weight of phenolic oil for the 1h reaction in supercritical ethanol was 873 g/mol,
3
whereas that of the 3h reaction was 1032 g/mol. Therefore, the average molecular weight of the
4
phenolic oils appeared to decrease during the 1st hour of SLD in supercritical ethanol, increase
5
during the 2nd and 3rd hours, and then decrease during hours 4 – 12. We propose that during the
6
1st hour of SLD in supercritical ethanol, the exposed portions of lignin were readily
7
depolymerized, particularly through cleavage of ferulate and p-coumarate end groups. During the
8
2nd and 3rd hours of SLD, the bulk of the lignin began depolymerizing, particularly through
9
cleavage of ß-O-4 bonds interconnecting lignin subunits. The resulting depolymerized fragments
10
of lignin during the 2nd and 3rd hours of SLD were primarily oligomeric, hence why the average
11
molecular weight of the oil increased.
12
Analysis of the HSQC 2D NMR plots (Figure 2) revealed that the phenolic oil from the SLD
13
process was predominantly aromatic in structure, consisting of syringyl (S) and guaicyl (G) type
14
lignin structures. Therefore, the phenolic oil was predominantly derived from lignin. Figure 2
15
shows spectra corresponding to the aromatic region (4 C/ 4 H at 150 – 90/6.0 – 8.0) and aliphatic
16
region (4 C/ 4 H at 90 – 50/3.0 – 5.0) for two different phenolic oils. There was no notable
17
difference in the HSQC spectra between phenolic oils produced in supercritical ethanol with and
18
without FM (Figures 2B/C & S11F/G). The aliphatic region of the spectra for the phenolic oil
19
produced in subcritical ethanol (Figure 2E) showed increased evidence of polysaccharides
20
(4 C/ 4 H at 60/3.6ppm, 65/3.4ppm, 70/3.5ppm), relative to the spectra for phenolic oil produced in
21
supercritical ethanol (Figure 2C).23 The increased detection of lignin-carbohydrate complexes in
22
the subcritical oil supported our initial hypothesis that subcritical ethanol is more reactive with
23
the holocellulose (polysaccharides) relative to supercritical ethanol. Evidence of ß-O-4 bonds in
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the subcritical oil (Figure 2.E) was obtained via strong signals for L-5 and L-6 (4 C/ 4 H at
2
72/4.85ppm, 84/4.4ppm), indicating these bonds had not been thoroughly cleaved.23,24 The L-5
3
and L-6 signals were however not present in spectra for supercritical oil (Figure 2.C), indicating
4
that the majority of the ß-O-4 bonds in lignin were cleaved in the supercritical state. The
5
aromatic region of the spectra for phenolic oil produced in subcritical ethanol (Figure 2.D)
6
lacked strong evidence of p-coumarate (pCA 2/6 - 4 C/ 4 H at 127.5/7.1ppm, 127.5/7.0ppm,
7
122.5/7.1ppm) and X1 (4 C/ 4 H at 131/6.3ppm) moieties.23,24 Considering the majority of p-
8
coumarate moieties exist as end groups to lignin fragments, they were likely depolymerized and
9
then repolymerized via condensation in subcritical ethanol. Whereas in supercritical ethanol
10
(Figure 2.B), the p-coumarate monomers were preserved via the stabilizing effect of ethanol in
11
the supercritical state.10
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pCA 2/6
FA/pCA 8
G5/6
FA/pCA 8
PB 2/6
X1 ! /#
FA/pCA 7
pCA 2/6
FA/pCA 7
C
E
Methoxy
Methoxy L-!
L-!
R-!
Cellulose
Xylan
Xylan L-#
R-!
L-"
1 2
Figure 2. Heteronuclear single quantum coherence (HSQC) 2D Nuclear Magnetic Resonance
3
(NMR) spectra of phenolic oil produced from 3h selective lignin depolymerization (SLD)
4
reactions of varying temperature and Fenton modification (FM) hydrogen peroxide loadings: A.)
5
The different moieties detected, B/C.) phenolic oil from SLD in supercritical ethanol with a 20%
6
FM hydrogen peroxide loading, D/E.) phenolic oil from SLD in subcritical ethanol with a 20%
7
FM hydrogen peroxide loading.
8
Fenton Modification for Improved Production of Phenolic Monomers
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1
The cumulative yields of the six major phenolic monomers are shown in Figure S10.
2
Considering the six major phenolic monomers constituted a maximum 19.1% of the initial
3
Klason lignin content, and the corresponding phenolic oil constituted 75.8%, there was a fair
4
amount of phenolic oil unaccounted for in the GC chromatograms. The unaccounted oil was
5
primarily composed of lignin-derived oligomeric phenols, supported by the 2D-NMR analysis.
6
The FM step did not affect the cumulative monomer yield for the 0.5h SLD reaction, and it
7
slightly increased the yield for the 1h SLD reaction. This observation supports our
8
aforementioned proposal that exposed pendant and end groups in lignin were readily
9
monomerized during the 1st hour of the SLD reaction, with or without FM. For the 3h SLD
10
reactions, the cumulative monomer yields were sensitive to the FM hydrogen peroxide loading,
11
with 5% and 20% loadings providing high (19.1 wt %) and low (12.8 wt %) yields, respectively.
12
The highest cumulative monomer yields were obtained with a 5% FM hydrogen peroxide
13
loading and 3h SLD reaction time (Table 1).
14
Table 1. Yields (w/w Klason lignin) of phenolic monomers and oils from the selective lignin
15
depolymerization process with varying reaction times. For all entries, the Fenton modification
16
hydrogen peroxide loading was 5%. Yield (wt%)
17
SLD Entry Reaction Time (h) 1 0.5 2 1 3 3
Monomers Monomers Phenolic 5 and 6 1-6 Oil 3.2% 6.1% 8.6%
10.6% 14.9% 19.1%
53.2% 64.5% 75.8%
18
Relative to a 5% FM hydrogen peroxide loading, a 20% loading caused a decrease in
19
cumulative monomer yields during the 2nd and 3rd hours of SLD (Figure S10) since the initial
20
Fenton induced free radical oxidation was excessive and led to undesirable holocellulose
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degradation and lignin condensation. It is known that the disruption of holocellulose and
2
condensation of lignin usually occur simultaneously in biomass pretreatment processes that
3
employ high temperatures and/or acid/base catalysts.6,25 We propose that oxidation of the
4
holocellulose during excessive FM increased its reactivity, such that its native structure was
5
degraded during the 2nd and 3rd hours of SLD. The degradation of holocellulose led to
6
undesirable side reactions with the depolymerized lignin, which ultimately led to lower monomer
7
yields. To support this proposal, evidence of holocellulose degradation during the 2nd and 3rd
8
hours of SLD was obtained from the enzymatic hydrolysis experiments, which are explained in
9
the subsequent section. The 5% FM hydrogen peroxide loading selectively targeted the lignin,
10
and therefore the holocellulose remained in its native form and was not degraded during the SLD
11
reaction.
12
The detection of monomers 5 and 6 was of interest due to the abundance of ferulate and p-
13
coumarate moieties in sweet sorghum bagasse. The yields of monomers 5 and 6 increased with
14
FM in all cases (Figure 3). The 3h SLD reaction with a 5% FM hydrogen peroxide loading gave
15
a maximum yield of 8.6 wt % for monomers 5 and 6, which equated to a 56.9% increase
16
compared to the control reaction. As shown in Scheme 1A, two plausible pathways are proposed
17
for the production of monomers 5 and 6, including a solvolytic transesterification of the exposed
18
ferulate and p-coumarate moieties in lignin and a reaction pathway induced by FM in which ß-O-
19
4 bonds are solvolytically cleaved (a detailed mechanism is shown in Scheme 1B). We propose
20
that monomers 1 and 2 were produced from decarboxylation of monomers 5 and 6, and
21
monomers 3 and 4 were produced from direct cleavage of ß-O-4 bonds.26
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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
Yield (w/w Klason lignin)
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10.0%
0.5h SLD Reaction Time
1.0h SLD Reaction Time
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3.0h SLD Reaction Time
8.0%
Ethyl Ferulate
6.0% 4.0%
Ethyl-PCoumarate
2.0% 0.0% 0%
5% 20% 0%
5% 20% 0%
5% 20%
Hydrogen Peroxide Loading (w/w biomass)
2
Figure 3. Yields of ethyl-p-coumarate (monomer 5) and ethyl ferulate (monomer 6) from
3
varying Fenton modification hydrogen peroxide loadings and selective lignin depolymerization
4
reaction times. The 0% hydrogen peroxide loadings represent the control experiments.
5
Ferulate and p-coumarate end groups only comprise a small fraction of mass in grasses.17
6
Therefore, the significant increase in yields of monomers 5 and 6 from the SLD process with FM
7
is believed to result from solvolytic cleavage of ß-O-4 bonds as illustrated in Scheme 1B. We
8
propose that FM increased the yields of monomers 5 and 6 due to the decrease in ß-O-4 bond
9
dissociation energy via hydroxyl and methoxy oxidation, as well as stabilizing effects from iron
10
chelation of aromatic substituents.11
11
Scheme 1B illustrates our proposed mechanism for solvolytic monomerization of lignin to
12
produce ethyl-p-coumarate (monomer 5) and ethyl ferulate (monomer 6) via direct ß-O-4 bond
13
cleavage. During FM, free radicals (•OH, •OOH) oxidized hydroxyl and methoxy groups and
14
iron chelation occurred at sterically unhindered aromatic substituents, as was reported in our
15
previous study.11 Oxidation of hydroxyls at both the alpha (carbon 2) and gamma (carbon 4)
16
positions is possible in the presence of appropriate oxidants, such as Fenton’s reagent, however,
17
the reaction presented herein proceeded only after gamma oxidation.11,27 In the first intermediate
18
reaction during SLD, the solvent (ethanol) reacted with the aldehyde to form a hemiacetal, which
19
then caused the ß-O-4 bond to cleave.28 The oxidized gamma position was favorable to
20
hemiacetal formation due to its lack of steric hindrance, relative to the alpha position. The final
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product is in its most stable form with ;-bond conjugation. Compared to our previous study,
2
which used an organosolv lignin from hardwoods, the FM step for the process presented herein
3
led to a higher selectivity for phenolic monomers. The stabilizing effects from iron chelation are
4
similar to those used by Shuai et al. in which formaldehyde reacted with lignin pendant groups to
5
form stable acetals.20 In Scheme 1B, substituting sterically-unhindered aromatic substituents with
6
bulky iron ions acted as a capping agent by preventing repolymerization of the phenolic
7
monomers obtained during the subsequent depolymerization reaction in supercritical ethanol. As
8
was the case for the cumulative monomer yields, the highest yields of monomers 5 and 6 were
9
produced from a 5% FM hydrogen peroxide loading and a 3h SLD reaction time.
10
Scheme 1. (A) The proposed reaction pathways for the production of the six phenolic monomers
11
during selective lignin depolymerization. (B) The proposed mechanism for solvolytic
12
monomerization of ethyl-p-coumarate (monomer 5) and ethyl ferulate (monomer 6) via direct ß-
13
O-4 bond cleavage.
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1 2
Fenton Modification for Improved Enzymatic Hydrolysis of the Holocellulose
3
The lignin-first approach to lignocellulosic biorefining aims to maximize the utilization
4
of both lignin and holocellulose components. In this study, after the SLD reaction was complete,
5
the holocellulose was separated from the phenolic oil as a “solid carbohydrate”. Enzymatic
6
hydrolysis of the solid carbohydrates was performed to understand how effective the SLD
7
reaction was at pretreating the biomass for liberation of both 5- and 6-carbon sugars. A 20%
8
hydrogen peroxide loading was chosen for the solid carbohydrates that underwent FM at
9
different reaction times. It was of interest to know whether the sugar yields from enzymatic
10
hydrolysis would follow a similar trend as the phenolic monomer yields did from SLD at
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different reaction times with this particular FM condition. As shown in Figure 4 and Table S3, a
2
maximum 66.1% of the solid carbohydrate mass was converted into free sugars within 24 hours.
3
The maximum sugar release data indicated that 79.9% of the initial 6-carbon polysaccharides
4
(glucan and galactan) and 62.7% of the initial 5-carbon polysaccharides (xylan and arabinan)
5
were converted into free sugars (See Table S4). For most of the enzymatic reactions, the solid
6
carbohydrates that had undergone FM liberated sugars in a higher abundance and at a faster rate
7
than the controls, indicating FM enhanced enzymatic activity. Scanning electron microscopy and
8
energy-dispersive x-ray spectroscopy were used to confirm chelated iron from FM remained
9
bound to the biomass after the SLD reaction (see Figures S12-S16). The solid carbohydrate from
10
the 1h SLD with FM had the highest catalytic effect, with a 23.7% increase in conversion yield
11
relative to the control after the 1st three hours and a sustained effect over subsequent time points,
12
as shown in Figure 4. In nature, various fungal species feed on woody biomass via transition-
13
metal mediated oxidation of lignin and hemicellulose followed by enzymatic hydrolysis of the
14
polysaccharides.29 Therefore, the biomimetic nature of the initial FM step increased the
15
enzymatic digestibility of the biomass. In addition, the stabilizing effect of the chelated iron
16
during SLD in supercritical ethanol limited char formation, thus enhancing enzymatic activity by
17
allowing for less non-productive binding and more accessibility to the polysaccharides. The solid
18
carbohydrate from the 3h SLD was enzymatically hydrolyzed at a slower rate than both the 0.5
19
and 1h solids, with and without FM. We propose that the relatively low sugar yields from the
20
solid carbohydrates that underwent 3h SLD were caused by different mechanisms for the
21
reactions with and without FM. With FM, the holocellulose was degraded during the 2nd and 3rd
22
hours of SLD due to excessive oxidation, as was explained in the previous section. Without FM,
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the long reaction time and absence of stabilizing iron ions led to char formation, thus reducing
2
the accessibility to the enzymes. SLD Reaction Time (h)
Percent Conversion (w sugar / w solid carbohydrate)
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
Page 20 of 27
75% 0.5 1.0 3.0
0.5 1.0 3.0
65% Control
55% 45%
Fenton Modified
35% 25% 3
3
0.5 1.0 3.0
0.5 1.0 3.0
6
12
24
Enzyme reaction time (h)
4
Figure 4. Percent conversion of solid carbohydrates to free sugars (5-carbon + 6-carbon) via
5
enzymatic hydrolysis. A 20% hydrogen peroxide loading was used for the solid carbohydrates
6
that had undergone Fenton modification.
7
CONCLUSIONS
8
A new lignin-first biorefining process was developed to effectively utilize all three major
9
components of sweet sorghum bagasse (lignin, hemicellulose, and cellulose). Fenton’s reagent
10
proved to be successful in enhancing both lignin depolymerization and enzymatic hydrolysis of
11
the holocellulose. The supercritical state of ethanol proved to be advantageous for lignin
12
depolymerization and holocellulose preservation, relative to the subcritical state. The benefits of
13
this process in comparison with other SLD processes include the use of an inert atmosphere,
14
earth abundant catalyst, reasonable reaction time, and green solvent. The process presented
15
herein could be improved with further investigation into the purification of the phenolic
16
monomers and their application in high-value products. Overall, the novelty presented herein has
17
contributed to the rapidly growing field of lignin-first biorefining by cost-effectively utilizing
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Fenton’s reagent and supercritical ethanol without hydrogen to produce valuable phenolics and
2
free sugars.
3 4
ASSOCIATED CONTENT
5
Supporting Information
6 7 8 9
The Supporting Information is available free of charge on the ACS Publications website at DOI: Contains figures, tables, and additional descriptions of procedures. AUTHOR INFORMATION
10
Corresponding Author
11
*Email:
[email protected] 12
AUTHOR CONTRIBUTIONS
13 14
The manuscript was written through contributions of all authors. All authors have given approval to the final version of the manuscript.
15 16 17
ACKNOWLEDGEMENTS This work was financially supported by Biomass Research & Development Initiative
18
Competitive Grant no. 2001-10006-3058 from the USDA National Institute of Food and
19
Agriculture, by the U.S. Department of Energy’s International Affairs under award number DE-
20
PI0000031 from the U.S. Department of Energy’s Office of Energy Efficiency and Renewable
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1
Energy, Bioenergy Technologies Office; and the Institute of Agricultural and Food Sciences
2
(IFAS) graduate scholarship at the University of Florida. The authors kindly thank Dr. Wilfred
3
Vermerris for supplying the sweet sorghum bagasse and Novozymes® for supplying the enzyme
4
solutions.
5 6 7
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SYNOPSIS
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Reported herein is a new lignin-first approach to lignocellulosic biorefining in which whole
2
biomass is converted to high value phenolics and free sugars, via selective lignin
3
depolymerization prior to holocellulose by use of a cost-effective biomimetic catalyst and green
4
solvent.
5 6 7 8 9
TOC/ABSTRACT GRAPHIC Feedstock: Sorghum Bagasse
Fenton Modification
10
Fe3+/ H2 O2
Product 1: Phenolics
Product 2: C5 and C6 Sugars
Selective Lignin Depolymerization
Holocellulose Enzymatic Hydrolysis
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