Abstract
X-ray photoelectron spectroscopy (XPS) was used to trace pseudo lignin formation during the hydrothermal pretreatment of holocellulose and elaborate the structure of the isolated pseudo lignin. The results showed that XPS could detect the trace amounts of pseudo lignin in the pretreated holocellulose substrate by quantitative determination of carbon (C) and oxygen (O), while fourier transform infrared spectroscopy (FT-IR) and solid-state cross polarisation magic angle spinning carbon-13 nuclear magnetic resonance (CP/MAS 13C-NMR) almost had no responses. After extensive pretreatment, C1 increased from 8.9 to 23.0 %, O/C decreased from 0.68 to 0.54 along with an increase of Klason lignin of the pretreated holocellulose from 1.0 to 6.2 %. As for isolated pseudo lignin, both O1 and O2 were involved, whereas only O1 involved in reference lignin and O2 in holocellulose sample. In comparison to reference lignin, pseudo lignin was rich in C1 and less in C2, suggesting that more cyclic structures and hydroxyl groups were present in the pseudo lignin. The FT-IR and NMR results identified the presence of more aliphatic structures in the pseudo lignin, especially those formed initially; while the subsequent pretreatment could modify the aliphatic toward to aromatic structure.
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Introduction
X-ray photoelectron spectroscopy (XPS), also known as electron spectroscopy for chemical analysis (ESCA), is used to determine the quantitative elemental compositions, the bonding states of atoms as well as the locations of atoms in the samples (Kocaefe et al. 2013). Application of XPS to study fiber and pulp surface chemistry has been used extensively for many years, including surface composition and chemical modifications (Tóth et al. 1993; Chtourou et al. 1993; Xu et al. 2013).
In view of XPS, only peaks corresponding to C (carbon) and O (oxygen) are detected in pure cellulosic fibers; however, other elements such as N, Si, S and other metallic elements should also appear in the cellulosic fiber (Kocaefe et al. 2013; Rabemanolontsoa et al. 2011). The chemical shifts for carbon (Cls) in cellulosic fibers can be deconvoluted into four categories C1 (C–C/C–H), C2 (C–O), C3 (C=O/O–C–O) and C4 (O–C=O) (Nzokou and Kamdem 2005; Kamdem et al. 2003). C1 (C–C or C–H) arises mainly from lignin and extractives (Nzokou and Kamdem 2005; Johansson et al. 1999). The C1s peak centers around the bonding energy of 284 eV with a gradual decrease from C4 to C1. In terms of O1s peaks, O1 (C=O) and O2 (C–O) are generally involved; where, O1 is primarily assigned to oxygen in lignin, while O2 comes mainly from oxygen in carbohydrates. In fact, with an exception of C=O, C–O and C–O–C which are assigned to O2 are also found in lignin; however, most of hydroxyls and ethers in lignin are linked to at least one benzene ring, which results in a lower bonding energy of the oxygen core level electron because of greater polarizability of the aromatic substituents. The effect leads C–O and C–O–C in lignin to the lower binding energy and thus makes them assigning to O1 (Hua et al. 1993a). As a consequence, it is possible to monitor the amount of lignin by measuring elemental compositions and the oxygen–carbon (O/C) ratio from XPS. The O/C ratio has been shown to be proportional to the amount of C1 (Johansson et al. 1999; Rautkari et al. 2012); O/C can be used for quantitative determination of lignin content of the substrate (Shen and Parker 1999; Zhang et al. 2014). A high O/C reflects higher cellulose and/or hemicellulose content, while a low O/C suggests the presence of more lignin.
In our previous study from XPS, the hydrothermal pretreatment caused an increase of C1 and a decrease in O/C for the surface substance of bamboo chips, suggesting that lignin concentrated on the surface of bamboo chips. Moreover, O/C was found to decrease to a low level that closed to lignin (Ma et al. 2013). During the hydrothermal pretreatment of holocellulose, droplets gradually formed on the surface of the holocellulose fiber (Ma et al. 2014). Studies confirmed that these spheres almost entirely composed of hydrophobic lignin, which was termed as pseudo lignin (Sannigrahi et al. 2011). In theory, the cleavage of cellulose and hemicellulose has minimal effects on its relative content of C, O and O/C; however, the pseudo lignin generated from hydrothermal pretreatment of holocellulose could result an increase of C and a corresponding decrease of O. As a result, in this study, XPS was used to trace the pseudo lignin formation and compare structural differences between pseudo lignin and reference lignin.
Experiment
Holocellulose preparation
The starting material, holocellulose, was isolated from bamboo (Dendrocalamopsis oldhami) chips in the lab following the acid chlorite delignification process. In brief, the bamboo chips were split into small strips and then milled through a 40-mesh screen. Afterward, the bamboo sawdust was first extracted with benzene–ethanol solution with a Soxhlet extractor followed by acid chlorite delignification process. Acetic acid and chlorite were used to delignify the bamboo sawdust; the conditions were as follows: oven-dried bamboo sawdust (500 g), liquor solid ratio 8:1, acetic acid 10 % (based on the oven-dried bamboo powder weight), chlorite 40 %, temperature 70 °C, time 60 min, and treatment times 4. The holocellulose was washed by several times until the pH close to 7. The Klason lignin content of the holocellulose was determined to be 1.0 ± 0.2 % with Tappi standard (222om-06a) without benzene–ethanol extraction (Ma et al. 2014).
Hydrothermal pretreatment
Holocellulose (150 g) was placed in a canister specially designed to fit 1000 mL stainless steel pressure vessel. After the addition of 750 mL deionized water, the pressure vessel was tightly covered with a cap and was fitted on to a shaft. Where, the shaft could rotate in a cooking apparatus that was full of thermal oil (glycerinum), the schematic diagram of the apparatus was showed and detailed described in the literature (Ma et al. 2014). The temperature of the hydrothermal reaction was controlled by the oil and was kept at 170 °C. The reaction was carried out at four time intervals (30, 90, 150 and 240 min) under constant rotation provided by the shaft. Following completion, the pressure vessel was taken out and cooled with tap water. The pretreated samples were transferred to a fine-woven nylon bag for hydrolysate liquor removal; subsequently, the residual solid was collected and washed with deionized water. The solid residue was air-dried and then vacuum dried for further analysis.
Pseudo lignin isolation from hydrothermally pretreated holocellulose
Dioxane extraction of cellulase enzymatic hydrolysis of the ball-milled powder (CEL method) was used to isolate pseudo lignin from the pretreated holocellulose substrate (Guerra et al. 2006; Samuel et al. 2010). In brief, the vacuum-dried powder was rotary ball-milled in a porcelain jar with ceramic balls for 7 days; then, the milled powder was washed with acetic acid (HAc) and sodium acetate (NaAc) buffer (50 mmol/L, pH 4.8) and the concentration of powder-buffer mixture was kept at 20 %. Then the powder was subjected to two consecutive rounds of enzymatic hydrolysis with cellulase (Trichoderma reesei ATCC26921, Sigma) and cellobiase (Aspergillus niger, Sigma) for 2 days at 50 °C and shaken at a frequency of 150 rpm. Following centrifugation and washing the powder three times with deionized water, the powder was freeze dried. Afterward, the dried material was extracted with 96 % v/v dioxane twice at room temperature for 48 h; and then, the filtrate was recovered and concentrated. Ultimately, pseudo lignin was precipitated from the filtrate by adding water. The separate pseudo lignin was vacuum dried before the subsequent analysis. The pseudo lignin isolated from hydrothermally pretreated holocellulose was identified as PL-1 and PL-2 corresponding to the pretreatment times of 150 and 240 min, respectively. Meanwhile, the reference lignin (RL) was isolated from bamboo chips following the same procedure described above.
Acetylation of pseudo lignin and molecular weight determination
The molecular weight (MW) of the pseudo lignin was determined by GPC (gel permeation chromatography) analysis. Prior to GPC analysis, pseudo lignin was acetylated to improve its solubility in THF (tetrahydrofuran) using acetic anhydride/pyridine solutions (Samuel et al. 2010). In brief, dry pseudo lignin (100 mg) was dissolved in a 15 mL mixture of anhydride/pyridine (anhydride:pyridine = 2:1, v/v) and stirred at room temperature for 72 h in the absence of light. Thereafter, the acetylated lignin was precipitated from the mixture by adding 200 mL diethyl ether into the solution. While the acetylated lignin was freeze-dried, the samples were dissolved in the THF solution and kept the consistency of 10 mg/mL. The GPC analyses were carried out using Water GPC 2414 system consisting of three columns of Waters Styragel HR2, Waters Styragel HR3 and Waters Styragel HR4 linked in series and a refractive index (Water 2414, RI) detector. The mobile phase was THF with a flow rate 1.0 mL/min at 40 °C. The solution was filtrated with 0.45 μm membrane and injected into the GPC system for analysis, and polystyrene was used as the calibration standard. The number average molecular weight (Mn) and weight average molecular weight (Mw) were collected and processed using the Polymer Standards Service WinGPC Unity software. The polydispersity index of the molecular weight distribution was determined by calculating the ratio of Mw–Mn.
Characterizations
Solid-state cross polarisation magic angle spinning carbon-13 nuclear magnetic resonance (CP/MAS 13C-NMR) measurements of the holocellulose and pretreated holocellulose (240 min pretreatment) were carried out on a Bruker Avance III 500 instrument operating at a frequency of 125.5 MHz.
Fourier transform infrared (FT-IR) spectra of the samples were obtained from Thermo Nicolet Avatar 380 FT-IR instrument; where, the samples were pelletized with KBr powder. Each spectrum was recorded in the range from 4000 to 500 cm−1.
XPS (ESCAlab 250, ThermoFisher Scientific) measurements were performed on a Kratos Axis Ultra spectrometer with monochromatic Al Kα X-ray source. Both survey spectra and high-resolution spectra of C1s and O1s were collected. The atomic (C, O) composition and O/C was determined using the standard Scofield photoemission cross-sections from the XPS survey spectra; whereas the high-resolution spectra were used to differentiate and quantitate the C (C1, C2, C3) and O (O1 and O2) by curve fitting of C1s and O1s.
The soluble state 1H-NMR and 13C-NMR spectra were recorded on Bruker Avance III 500 MHz spectrometer operating at a frequency of 500 and 125.5 MHz respectively. Prior to NMR analysis, the pseudo lignin samples (~70 mg) were dissolved in deuterated dimethyl sulfoxide (DMSO-d6 0.5 mL) at 50 °C via ultrasonication.
Results and discussion
Pseudo lignin formation during holocellulose hydrothermal pretreatment
As well as acid pretreatment, the hydrothermal pretreatment of holocellulose also generated pseudo lignin, which was indicated by an increase of Klason lignin content in the pretreated holocellulose residue, as shown in Table 1. Of the small amounts of pseudo lignin formed during the hydrothermal pretreatment, only 6.2 % Klason lignin was detected in the holocellulose residue (170 °C, 240 min) and 54.1 % pseudo lignin could be isolated by CEL method. In contrast, 86.9 % of Klason lignin was present in the acid pretreated holocellulose substrate (0.20 M H2SO4, 60 min), while 51.3 % of the pseudo lignin was recovered by acid-dioxane extraction (Hu et al. 2012). The increase of the Klason lignin from acid pretreated residue probably suggested that acid and temperature were the main factors controlling the pseudo lignin formation. As reported by Hu, HMF (5-hydroxymethyl furfural) was the key intermediate to form pseudo-lignin (Hu and Ragauskas 2014). Moreover, cellulose degradation significantly enhanced as the temperature was elevated to 180 °C (Yan et al. 2014); more specifically, the decomposition of the sugars to HMF and F (furfural) aggravated with increasing acid concentrations (Roberto et al. 2003).
XPS characterizations of the hydrothermally pretreated holocellulose
Theoretically, C2 (C–O) is the predominant linkage in cellulose; accordingly, the O/C of cellulose is calculated as 0.83 in light of the gross formula (C6H10O5) (Hua et al. 1993a, b). In addition, O/C of hemicellulose, mainly represented by glucuronxylans, is approximately 0.8. Similar to pure cellulose, holocellulose was rich in C2 and O2. In principle, the O/C of holocellulose should be within the range 0.80–0.83; however, the presence of the trace lignin decreased the O/C of holocellulose to 0.68. Another possibility that the surface might be rich in lignin than the bulk would further decrease the O/C (Johansson et al. 1999).
Surprisingly as shown in Table 2, a higher O/C and a lower C1 has been found on the holocellulose surface when subjected to the 30 min pretreatment. The results were likely attributed to the fact that the dissolved long-chain hemicellulose fragments precipitated back onto the fiber due to the sharp decrease in solubility as the reactor was cooling (Zhang et al. 2010). After the initial pretreatment, a general increase of C1, decrease of C3 and O were observed. The evident increase of C1 was accompanied with the generation of pseudo lignin. Alternatively, the continual decrease of C3 (C=O/O–C–O) might ascribe to the decrease of the C=O/O–C–O, resulting from gradual cleavage of hemicellulose and cellulose.
The existence of C=O (C3) in the starting holocellulose, which originated from acetyl groups in xylan, could be verified by the presence of the peak at 1730 cm−1 in the FT-IR spectra as shown in Fig. 1, which disappeared when the hemicellulose encountered pretreatment (Laskar et al. 2013). Unfortunately, almost no peaks related to lignin were to be found in the FT-IR spectra even though 6.2 % of lignin was involved in the pretreated holocellulose substrate. In addition, the CP/MAS NMR spectra (Fig. 2) showed that the signals at 21 and 173 ppm, which were assigned to CH3 and C=O in acetyl group respectively, generally disappeared after holocellulose pretreatment because of the cleavage and degradation of O-acetyl in hemicellulose (Wikberg and Maunu 2004; Yelle et al. 2013). With the exception of the signals from cellulose and hemicellulose, weak signals between 140 and 160 ppm were observed and might be assigned to aromatic structure of lignin.
Pseudo lignin formation could be identified by lignin quantitation of the pretreated holocellulose; unfortunately, FT-IR and CP/MAS-NMR could not provide additional promising information because of the small amount of pseudo lignin. In spite of this, pseudo lignin formation could be observed by XPS analysis according to a sharp rise of C1 and a decrease in O/C.
XPS characteristics of pseudo lignin
Studies have reported that pseudo lignin consisted of carbonyl, carboxylic, aromatic and aliphatic structures (Sannigrahi et al. 2011; Hu et al. 2012), however, the pseudo lignin structure has not been thoroughly investigated and remains obscure.
The high resolution scans of C1s and O1s were shown in Fig. 3a, b, whereas the deconvoluted peaks of oxygen of pseudo lignin were shown in Fig. 3c. It was apparent that C1 represented the majority of the carbon atoms in pseudo lignin, while C2 was the primary component of holocellulose. As for O1s scans, the bonding energy decreased from single-bonded oxygen in holocellulose to double bonded oxygen or single-bonded oxygen in reference lignin. The results further confirmed that oxygen in holocellulose came mainly from O2, whereas O1 are almost derived from lignin. Alternatively, both O1 and O2 were present in the pseudo lignin; the results might suggest that fewer hydroxyl or ethers were connected to benzene rings. As discussed earlier, the linkage between hydroxyl or ethers and benzene rings was the origin of the lower bonding energy of oxygen in hydroxyl and ethers. As shown in Table 3, pseudo lignin isolated from extensive pretreatment resulted in slightly higher O1 and extremely lower O2 (10.2 vs 9.8; 8.5 vs 16.0); the drastic decrease of O2 from PL-1 to PL-2 suggested that the reactions towards pseudo lignin during hydrothermal pretreatment might take place at C–OH or C–O–C groups.
Although O/C and total C content of PL-1 was similar to the reference lignin and soda lignin (Table 3), the presence of more C1 and less C2 in PL-1 suggested that pseudo lignin was rich in ring structures and hydroxyl groups (C–O–H) because of the contribution to higher C1 and lower C2; by contrast, ether linkage (C–O–C) linkage resulted a higher C2. It was reported that no open chain intermediates were found in xylose degradation products under acidic medium (Qian et al. 2005), while furfural might react with the intermediates of the xylose-to-furfural conversion and thus furfural-xylose complex might be formed (Zeitsch 2000). As a result, more alicyclic structures and C–OH (or less C–O–C) were assumed to present in the pseudo lignin.
As the pretreatment proceeded, C1 increased alongside a decrease of C2, C3 and total O, suggesting that oxygen contained functional groups might participate in condensation reactions with pseudo lignin itself or carbohydrate degradation products. The Mw and Mn of the pseudo lignin shown in Table 4 indicated repolymerization reactions; therefore aromatic rings can be alkylated significantly to produce heavy condensation compounds. The O/C of PL-2 decreased to an extremely low level and was calculated as 0.24; the low O/C value might indicate the condensed structure. Additional evidence of condensation reactions between lignin fragments also included an increase in lignin carbon–carbon bonds (Trajano et al. 2013); the results were in agreement with the C1 content by XPS analysis.
The increase in C and decrease in O were also observed during biomass pretreatment, et al. C9-formula calculated for the milled wood lignin (MWL) isolated from the native Eucalyptus globulus and pretreated substrate was C900H860O322(OCH3)141 and C900H748O283(OCH3)140, respectively. Following pretreatment, the O/C was reduced (Leschinsky et al. 2008a, b). Lignin residues after autohydrolysis of extractive-free aspen wood meal at 195 °C was found to be higher in carbon but lower in hydrogen and oxygen than aspen milled wood lignin (Wayman and Chua 1979). Results from a study surrounding phenolic compounds and lignin hydrothermal pretreatment showed that ether bonds were more easily broken than the C–C bonds (Barbier et al. 2012). Substantial cleavage of arylether and depletion of OCH3 in lignin that experienced in biomass pretreatment might also be applicable in the pseudo lignin. These two effects could cause a decrease of O and O/C.
FT-IR and NMR spectra of pseudo lignin
As shown in Fig. 4a, pseudo lignin isolated from hydrothermally pretreated holocellulose shows the stretches for the O–H, C–H, C=O, aromatic C=C at 3440, 2932, 1703 and 1605/1510 cm−1, respectively; which are the general structures involved in pseudo-lignin. In addition, the peak at 867 cm−1 arising from C–H out-of-plane bending suggests the benzene rings of pseudo-lignin are 1,3,5-trisubstituted (Hu et al. 2012). Other peaks at 1452, 1420, 1328 and 1115 cm−1 are likely assigned to the stretches of C=C/C–C, C–O–C, C–H of aromatic rings. More precisely, as shown in Fig. 4b, the relative intensities of the band at 1110 cm−1 (deformation vibrations of C–H of aromatic rings or C–O in alcohols or aliphatic ethers) to the band at 1605 and 1510 cm−1 (aromatic ring vibrations) were to be found in pseudo lignin rather than the reference lignin (Casas et al. 2012), which might be the structural disparities between reference lignin and pseudo lignin. Because of the weak intensity of the band at 1605 and 1510 cm−1, the strong band at 1110 cm−1 might be assigned to the C–O in aliphatic structure; suggesting that more aliphatic hydroxyl groups and less aromatic structures appeared in pseudo lignin.
As shown in Fig. 5a, b of the 1H-NMR spectra of the pseudo lignin, the signals between 6.0 and 8.0 ppm belonged to aromatic protons, whereas those between 0.8 and 1.5 ppm were assigned to the aliphatic moiety (Park et al. 1991; Tejado et al. 2007). Upon comparison with reference lignin (Fig. 6a), it was found that more aliphatic protons were present in pseudo lignin PL-1, whereas, a decrease in aliphatic protons and an increase in aromatic protons were to be found in PL-2. That was to say, the pseudo lignin formed initially might be rich in aliphatic structures. Afterward, the conversion of aliphatic to aromatic structures or the depletion of aliphatic structures might occur. In addition, the signals at 2.2 and 2.5 ppm, which might be attributed to protons in carboxylic acid or ester bond (α position) or in the acetyls connected to the benzene ring, weakened probably due to the cleavage of ester cleavage (Zoia et al. 2012; Choi and Faix 2011).
Corresponding to the 13C-NMR spectra shown in Fig. 5c, the signals centered at 56.4 and 60.6 ppm were assigned to methoxyl groups connected to an aromatic ring, which were also identified by the signals between 3 and 4 ppm in 1H-NMR spectrum. The origin of methoxyl group of the pseudo lignin was probably coming from 4-O-methyl-glucuronic acid in hemicellulose fractions (Hu et al. 2012; Hu and Ragauskas 2014). Besides, the comparative analysis of 13C-NMR between pseudo lignin (Fig. 5c) and reference lignin (Fig. 6b), also affirmed that more aliphatic structure were involved in pseudo lignin rather than reference lignin. Accordingly, decreasing signals at 5–40 and 70–80 ppm (attributed to aliphatic structures) from PL-1 to PL-2 were also found in 13H-NMR spectra (Kanitskaya et al. 2012), suggesting that pretreatment could convert the aliphatic structures to aromatic structure or deplete the aliphatic structure. As for the aromatic region (100–160 ppm), significant structure modifications also had been observed.
Combining the results of XPS, FT-IR and NMR, as well as Hu’s study (Hu et al. 2012), pseudo lignin generated from holocellulose hydrothermal pretreatment consisted primary of carbonyl, aromatic and aliphatic structures; furthermore, more alicyclic structures and aliphatic hydroxyl groups existed in pseudo lignin. Besides, more aliphatic structures were found in pseudo lignin as opposed to reference lignin, especially for the pseudo lignin formed initially. The pretreatment modified the structure of the pseudo lignin significantly toward to an aromatic leading structure and gave rise to an increase of MW.
Conclusions
XPS, as a novel technique, can be used to determine small amounts of pseudo lignin generated in hydrothermally pretreated holocellulose by quantitative analysis of C and O atoms. During holocellulose pretreatment, C1 increased from 8.9 to 23.0 % along with an increase in Klason lignin from 1.0 to 6.2 %. Degradation of holocellulose and subsequent reactions between degradation products caused a decrease in C2, C3 and O2; however, drastic increase of C1 led to a lower O/C. In regards to pseudo lignin isolated from pretreated holocellulose, pseudo lignin had an extremely high content of C1 and a low C2 for an equivalent total C and O atoms with reference lignin; accordingly, more alicyclic structures and hydroxyl groups might be involved in pseudo lignin. Moreover, the pseudo lignin formed initially was rich in aliphatic structures, and the pretreatment might convert or deplete the aliphatic structures, and therefore pseudo lignin was toward to aromatic leading compounds.
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Acknowledgments
The authors acknowledge the support from Natural Science Foundation of Fujian Province, China, 2012J01065 and Forestry Department of Fujian Province, China, [2012]2 and Scientific Research Foundation of Graduate School of Fujian Agriculture and Forestry University, 324-1122yb002.
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Ma, X., Yang, X., Zheng, X. et al. Toward a further understanding of hydrothermally pretreated holocellulose and isolated pseudo lignin. Cellulose 22, 1687–1696 (2015). https://doi.org/10.1007/s10570-015-0607-1
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DOI: https://doi.org/10.1007/s10570-015-0607-1