纤维素在离子液体[AMMor]Cl/[AMIm]Cl混合溶剂中的均相乙酰化反应研究

利用混配离子液体N-烯丙基-N-甲基吗啉氯盐(N-allyl-N-methylmorpholinium chloride,[AMMor]Cl)和1-烯丙基-3-甲基咪唑氯盐(1-allyl-3-methylimidazolium chloride,[AMIm]Cl)作为溶剂,乙酰氯为乙酰化试剂,研究了在没有催化剂条件下的纤维素的均相乙酰化反应.生成的醋酸纤维素(CA)的取代度由2.58到3.00.用FT-IR,1HNMR和13CNMR进行表征.结果表明,[AMMor]Cl/[AMIm]Cl混配的离子液体是一种良好的均相乙酰化介质,纤维素C-6,C-3和C-2三个位置上的羟基均发生了乙酰化反应,且得到纯的纤维素醋酸酯.此反应方便可控,简单高效,不仅降低了成本,离子液体比较容易回收,可以再次利用.     

微波法合成离子液体[AMIM]Cl及其对纤维素的预处理

利用微波法合成了离子液体1-烯丙基,3-甲基咪唑氯盐[AMIM]Cl,并利用合成的离子液体分别对微晶纤维素、麦草秸杆和玉米芯进行预处理,得到了再生纤维素。考察了纤维素在离子液体中的溶解过程,并通过FT-IR、SEM和酶解对其预处理效果进行了表征。结果表明:微波法可以大大减少反应时间,合成的离子液体[AMIM]Cl可以有效降低纤维素的结晶度,增加其表面粗糙度,提高纤维素酶的可及性及底物的利用率。     

共溶剂存在下N-烯丙基吡啶氯盐离子液体对纤维素的溶解性能研究

采用一步法合成N-烯丙基吡啶氯盐离子液体([APy]Cl),考察其对纤维素的溶解性能.结果发现,在120℃下对棉浆粕(聚合度(DP)=556)的溶解度可高达19.71%,但再生后聚合度为223,热降解严重.通过添加不同种类共溶剂的方法克服此缺点.结果表明,有机溶液(DMSO,DMAc,DMF或吡啶)作为[APy]Cl的共溶剂时,[APy]Cl/DMAc复合溶剂对棉浆粕的溶解效果最佳,100℃下溶解度为15.03%,再生后聚合度为403.此外降低了溶剂成本.但70℃下,溶解度仅为1.36%,溶解能力较弱.继续探讨了[AMIM]Cl作为[APy]Cl的共溶剂时对纤维素的溶解性能,结果表明,70℃下,[APy]Cl/[AMIM]Cl复合溶剂对棉浆粕的溶解度为8.78%,再生后聚合度为516.可知添加上述2种共溶剂均使[APy]Cl在低于自身熔点下形成液体并能够溶解一定量纤维素,拓宽了溶解温度区间及应用平台.对FTIR,XRD和TGA谱图分析,结果表明上述为纤维素的直接溶剂,可将其晶型由Ⅰ型转变成Ⅱ型,再生后热稳定性稍有降低.通过照片和SEM表明再生膜无色透明,结构致密.     

[Amim]Cl离子液体中微波辐射加热促进稻草秸秆酸水解制备还原糖

在1-烯丙基-3-甲基咪唑氯盐([Amim]Cl)离子液体介质中,用微波辐射加热促进稻草秸秆纤维素的酸水解,探讨了微波辐射加热及离子液体对酸催化植物纤维素水解的促进作用;并对水解产物中的还原糖进行了测定,着重考察了离子液体用量、硫酸浓度、微波功率、反应温度、反应时间等因素对还原糖收率的影响.结果表明,在[Amim]Cl...     

1-烯丙基-3-甲基咪唑离子液体单体与丙烯腈共聚行为的研究

以1-烯丙基-3-甲基咪唑盐酸盐([AMIM]Cl)作为离子液体单体,偶氮二异丁腈作为引发剂,二甲基亚砜为溶剂,实现了与丙烯腈(AN)在不同反应条件下的自由基共聚合.研究了AN/[AMIM]Cl二元共聚合的动力学,得到了相应的竞聚率数据(rAN=8.11,r[AMIM]Cl=0).用1H-NMR、GPC、DSC、TGA等手段对共聚物进行了表征.通过对AN/[AMIM]Cl二元共聚及AN/IA/[AMIM]Cl三元共聚的研究发现,[AMIM]Cl在与丙烯腈共聚时具有双重作用,一部分离子单体进入到共聚物的分子链中调节其亲水性及可纺性,剩下的大部分留在纺丝液中可显著降低纺丝液的黏度,从而使高分子量高固含量纺丝液的纺制成为可能,有望得到高性能的碳纤维原丝.     

离子液体[BMIM]Cl预处理对微晶纤维素酶解的影响

以微晶纤维素为研究对象, 设计了离子液体1-丁基-3-甲基咪唑氯盐(1-butyl-3-methylimidazolium chloride, [BMIM]Cl)预处理微晶纤维素Avicel的实验方法以实现纤维素的高效酶解糖化. 在[BMIM]Cl中Avicel完全溶解, 经水洗沉淀得到再生纤维素, 回收后的离子液体可重复利用. 预处理后底物酶解的可溶性糖转化率在24 h时高达94.65%, 较之同样条件下未经预处理底物的酶解糖转化率(48.57%)有飞跃性提升. 进一步考察了离子液体预处理对纤维素结构及形态的影响, 结果表明: [BMIM]Cl预处理后Avicel氢键减弱; 结晶度明显下降, 结晶型态由纤维素I型转变为纤维素II型; 由规整的平行排布转变为疏松有孔的无序形貌. 正是离子液体预处理引起的纤维素微观与宏观结构性质的显著改变使得再生后纤维素酶解的可溶性糖转化率大幅提高.     

[AEIM]Cl的合成及微波溶解微晶纤维素

以氯丙烯和N-乙基咪唑为原料合成了离子液体氯化1-烯丙基-3-乙基-咪唑盐([AEIM]Cl),利用FT-IR和¹HNMR对其化学结构进行了表征。采用微波加热法溶解微晶纤维素(MCC),考察 [AEIM]Cl对纤维素的溶解性能。研究了NaOH、微波和高压等3种预处理方式对微晶纤维素的相对结晶度、聚合度及溶解率的影响。利用FT-IR、XRD、TGA和SEM分别对溶解后得到的再生纤维素的化学结构、晶型变化、热稳定性及表观形貌进行测试与分析。结果表明,合成的离子液体是目标产物,对微晶纤维素表现出很好的溶解能力,且高温高压条件下15％的NaOH水溶液对微晶纤维素处理后,得到的纤维素相对结晶度最小,聚合度最低,溶解率最高。溶解过程中纤维素没有发生衍生化反应,溶解后得到的再生纤维素的相对结晶度和微晶尺寸变小,热稳定性降低。     

双螺杆挤出机纺制的纤维素纤维

以离子液体氯化1-烯丙基-3-甲基咪唑([AMIM]Cl)为溶剂,采用双螺杆挤出机溶解并纺制了较高质量分数的纤维素纤维,测定了纤维素纤维的结构与性能以及纤维中[AMIMCl]残余质量分数,观察了纤维的微观形貌。结果表明:双螺杆挤出机能溶解并纺制较高质量分数的纤维素纤维,可达30%,纤维素纤维晶型由浆粕的Ⅰ型转变为Ⅱ型,纤维结晶度小于纤维素浆粕。成形过程中,纤维中的离子液体难于完全除去,导致纤维素纤维分解温度下降。实验范围内,纤维素质量分数为20%时,纤维断裂强度最高,为0.51cN/dtex。     

纤维素-[Amim]Cl浓溶液的稳态流变规律

对纤维素-氯代1-烯丙基-3-甲基咪唑([Amim]Cl)浓溶液在不同温度下的稳态流变规律进行了研究。测试结果显示:纤维素-[Amim]Cl浓溶液属于假塑性流体。运用Cross和Carreau两种黏度模型对实验数据进行拟合,得到了表观黏度的主曲线,通过Arrhenius方程确定了移位活化能(ΔEa)为91.86~164.97 kJ/mol。与纤维素-氯代1-丁基-3-甲基咪唑([Bmim]Cl)溶液、纤维素-N-甲基吗啉-N-氧化物(NMMO)溶液、熔融聚合物(如聚丙烯、聚乙烯等)的活化能以及流变规律进行了对比。结果表明,纤维素-[Amim]Cl浓溶液的ΔEa较高,温度对体系黏度影响较大。     

细菌纤维素在室温离子液体中的溶解性能

研究了细菌纤维素(BC)在绿色溶剂1-烯丙基-3-甲基氯代咪唑室温离子液体中的溶解行为,通过偏光显微镜观察了BC在此离子液体中的溶解过程,热失重(TGA)和红外光谱(FT-IR)测试了再生前后BC的性能,探索了BC在离子液体中溶解、再生的可能性和可行性.结果表明:离子液体是BC的优良溶剂,对BC的溶解属于直接溶解,不发生其他的衍生化反应;再生后BC的热稳定性变好,且离子液体可回收利用.     

Dual effects of dimethylsulfoxide on cellulose solvating ability of 1-allyl-3-methylimidazolium chloride

Polar aprotic solvents are considered to act as cosolvents with ionic liquids (ILs) for cellulose, strengthening the solvating ability of ILs by improving their cellulose solvating kinetics without influencing the solubility of cellulose in ILs. In this work, it was found that dimethylsulfoxide (DMSO) at low concentration improves the cellulose solvating ability of [AMIM][Cl], but weakens it at high concentration. To clarify the mechanism of these dual effects of DMSO on the cellulose solvating ability of [AMIM][Cl], the [AMIM][Cl]/DMSO system was investigated using excess infrared spectroscopy, nuclear magnetic resonance (NMR) T ₂ relaxometry, ¹H NMR, ³⁵Cl NMR, and dynamic light scattering. The results indicate that the tight association between the cation and anion in the [AMIM][Cl] network is loosened at low DMSO concentration. As a result, mass transport is accelerated due to the enhanced dynamics of [AMIM][Cl], promoting the cellulose solvating kinetics of [AMIM][Cl]. However, ion clusters of [AMIM][Cl] start to form when the molar fraction of DMSO (x _DMSO) exceeds 0.5. The hydrogen bonds between cations and anions in the ion clusters become much stronger than in pure [AMIM][Cl], leading to decreased ability of [AMIM][Cl] to form hydrogen bonds with cellulose and thus decreased cellulose solubility in the [AMIM][Cl]/DMSO mixture.     

1-烯丙基,3-甲基咪唑室温离子液体的合成及其对纤维素溶解性能的初步研究

随着不可再生资源 (如石油、天然气、煤矿和金属矿藏等 )的急剧耗竭 ,天然高分子的开发与利用日益引起世人的关注 .纤维素作为自然界中最丰富的天然高分子材料 ,其开发与利用一直备受关注[1] .但由于天然纤维素较高的结晶度和分子间和分子内存在大量的氢键 ,使其具有不熔化、在大多数溶剂中不溶解的特点 ,这成为纤维素在应用开发中的最大障碍 .开发有效的纤维素溶剂体系是解决这一难题的关键 .研究较多的纤维素溶剂主要有铜氨溶液、Ｎ 甲基吗啉 Ｎ 氧化物(ＮＭＭＯ)溶剂体系 ,氯化锂 二甲基乙酰胺 (ＬｉＣｌ ＤＭＡＣ)溶剂体系等[2 ] ,而这…     

新型功能化离子液体[HeEIM]Cl的合成及其对棉纤维的溶解性能

合成了离子液体氯化1-(2-羟乙基)-3-乙基-咪唑([HeEIM]Cl), 并利用FTIR和1HNMR对其化学结构进行了表征. 考察了NaOH、微波和高压等处理方式对棉纤维的结晶度、聚合度(DP)和溶解率的影响. 研究了不同的溶解温度在微波加热和传统加热条件下对棉纤维的溶解率和再生纤维素的聚合度的影响. 利用FTIR, XRD, TGA和SEM等方法分别对溶解后得到的再生纤维素的化学结构、结晶度变化、热稳定性和表观形貌进行了分析. 结果表明, 合成的离子液体对棉纤维表现出很好的溶解能力, 且在溶解和再生过程中未发生化学变化. 棉纤维在高压条件下经质量分数为30%的NaOH预处理后, 溶解性能最佳. 微波加热法的溶解效果远远优于传统加热法, 且随着温度的升高, 溶解率逐渐增大. 溶解后得到的再生纤维素的结晶度变小, 聚合度下降, 热稳定性降低.     

Cellulose solvent-based pretreatment for corn stover and avicel: concentrated phosphoric acid versus ionic liquid [BMIM]Cl

Since cellulose accessibility has become more recognized as the major substrate characteristic limiting hydrolysis rates and glucan digestibilities, cellulose solvent-based lignocellulose pretreatments have gained attention. In this study, we employed cellulose solvent- and organic solvent-based lignocellulose fractionation using two cellulose solvents: concentrated phosphoric acid [~85?% (w/w) H₃PO₄] and an ionic liquid Butyl-3-methylimidazolium chloride ([BMIM]Cl). Enzymatic glucan digestibilities of concentrated phosphoric acid- and [BMIM]Cl-pretreated corn stover were 96 and 55?% after 72?h at five filter paper units of cellulase per gram of glucan, respectively. Regenerated amorphous cellulose by concentrated phosphoric acid and [BMIM]Cl had digestibilities of 100 and 92?%, respectively. Our results suggested that differences in enzymatic glucan digestibilities of concentrated phosphoric acid- and [BMIM]Cl-pretreated corn stover were attributed to combinatory factors. These results provide insights into mechanisms of cellulose solvent-based pretreatment and effects of residual cellulose solvents and lignin on enzymatic cellulose hydrolysis.     

Effects of Cationic Structure on Cellulose Dissolution in Ionic Liquids: A Molecular Dynamics Study

In recent years, great progress has been made in the dissolution of cellulose with ionic liquids (ILs). However, the mechanism of cellulose dissolution, especially the role the IL cation played in the dissolution process, has not been clearly understood. Herein, the mixtures of cellulose with a series of imidazolium‐based chloride ionic liquids and 1‐butyl‐3‐methyl pyridinium chloride ([C₄mpy]Cl) were simulated to study the effect that varying the heterocyclic structure and alkyl chain length of the IL cation has on the dissolution of cellulose. It was shown that the dissolution of cellulose in [C₄mpy]Cl is better than that in [C₄mim]Cl. For imidazolium‐based ILs, the shorter the alkyl chain is, the higher the solubility will be. In addition, an all‐atom force field for 1‐allyl‐3‐methyl imidazolium cation ([Amim]⁺) was developed, for the first time, to investigate the effect the electron‐withdrawing group within the alkyl chain of the IL cation has on the dissolution of cellulose. It was found that the interaction energy between [Amim]⁺ and cellulose was greater than that between [C₃mim]⁺ and cellulose, indicating that the presence of electron‐withdrawing group in alkyl chain of the cation enhanced the interaction between the cation and cellulose due to the increase of electronegativity of the cations. These findings are used to assess the cationic effect on the dissolution of cellulose in ILs. They are also expected to be important for rational design of novel ILs for efficient dissolution of cellulose.     

Thermal stability and lifetime of [AMIM]Cl-PFSA composite membranes

1-Allyl-3-methylimidazolium chloride [AMIM]Cl hybrid perfluorosulfonic acid (PFSA) composite electrolyte membrane was prepared and characterized by TG and FTIR technique. The conductivity was measured using AC impedance method. The results showed that when raised from 20 to 90 °C, the conductivity of composite membrane was increased from 4.50 × 10⁻⁶ to 1.34 × 10⁻⁵ S cm⁻¹, before and after the modification of triethylamine, the thermal stability of composite membrane was not changed, but the TEA-PFSA with [AMIM]Cl reactivity was a little difference. However, the heat resistance of composite membrane was significantly enhanced compared with that of PFSA membrane, the peak temperature of composite membrane almost disappeared in first stage, and offset to the high-temperature zone. When heated at 350 °C, the decomposition rate of PFSA, 10%[AMIM]Cl-PFSA and 10%[AMIM]Cl-TEA-PFSA membrane was 13.71, 3.67 and 1.26%, respectively. If the decomposition process follows isothermal first-order reaction and the conversion rate α is 10%, the activation energy E _α of the composite membrane is 97.4 kJ mol⁻¹. Besides, the isothermal lifetime of composite membrane was also measured.

     

Preparation and characterization of cellulose-ZnO nanocomposite based on ionic liquid ([C4mim]Cl)

Cellulose-ZnO composite was achieved by microwave assisted dissolution of cellulose in ionic liquid 1-butyl-3-methylimidazolium chloride ([C₄mim]Cl) followed by addition of premixed ground of Zn(CH₃COO)₂·2H₂O and NaOH. Surface characterization, optical property and thermal stability of nanocomposite were determined by X-ray diffraction, scanning electron microscopy (SEM), UV–Vis spectroscopy and thermo gravimetric analysis. XRD patterns showed the ZnO in polymer matrix has the wurtzite structure. Presence of zinc oxide nanoparticles and cellulose fibers in the composites were observed by SEM. Band-edge transition of zinc oxide in the nanocomposite occurs in lower wavelength than bulk zinc oxide. Thermal stability of nanocomposite was lower than regenerated cellulose due to catalyst behavior of zinc oxide nanoparticles in cellulose matrix.