一、学术论文 [1] ren h.*, lai y.z., amidon t.e. understanding the behavior of lignin in fractionation of wood polmers by carboxymethylation. journal of biobased materials and bioenergy, 2011, 5, 365-370 [2] ren h.*, omori s. a higher brightening of mechanical pulps, cellulose chemistry and technology, 2012,46(1-2), 115-120 [3] ren h.*, omori s. a simple preparation of betulinic acid from sycamore bark, journal of wood science, 2012,58,169-173 [4] ren h.*, zhai h.m., zhang y., jin y.c., omori. s. isolation of acetosyringone and cinnamic acids from straw soda cooking black liquor and simplified synthesis of hydroxyacetophenones, cellulose chemistry and technology, 2013, 47(3-4), 219-229 [5] ren h.*, omori s. an attempt to produce bio-diesel from pulping byproducts, japan tappi, 2013, 67(5), 74-83 [6] ren h.*, omori s. comparison of isolated hemicelluloses from soda cooking black liquor,commercial and bacterial xylan, cellulose chemistry and technology, 2014, 48(7-8), 675-681 [7] ren h.*, liu z.l., zhai h.m., cao y.f., omori s. effects of lignophenol on mechanical performance of biocomposites based on phb reinforced with pulp fibers—a comparative polypropylene study, bioresources, 2015, 10(1), 432-447 [8] ren h.*, qian s., omori s. solubilization of graminaceus plants in water by carboxy methylation, journal of wood science, 2015, 61(2), 199-203 [9] ren h.*, dai x., zhai h.m., liu z.l., omori s. comparison of bamboo native lignin and alkaline lignin modified by phase-separation method, cellulose chemistry and technology, 2015, 49(5-6), 429-438 [10] ren h.*, zhang y., zhai h.m, chen j.x. production and evaluation of biodegradable composites based on polyhydroxybutyrate and polylactic acid reinforced with short and long pulp fibers, cellulose chemistry and technology, 2015, 49(7-8), 641-652 [11] ren h.*, dai x., omori s. preparation of bio-diesel and separation of hemicellulose from soap skimmings, cellulose chemistry and technology, 2016, 50(2), 247-255 [12] dai x., qian s., ren h.*, omori s. the effect of bamboo (sinocalamus affinis) lignophenols as a natural adhesive on different pulp sheets, bioresources, 2015, 10(2), 3146-3153 [13] qian s., dai x., qi y.l., ren h.* preparation and characterization of polyhydroxybutyrate-bamboo lignophenol biocomposite films, bioresources, 2015, 10(2), 3169-3180 [14] qian s., ren h.*, dai h.q., omori s. characterization of polypropylene fiber and lignocresol enhanced poly(3-hydroxybutyrate) composite films, bioresources, 2016, 11(3), 7036-7045 [15] liu b., qian s., dai h.q., ren h.* separation and utilization of cell wall components by using kraft pulping method, bioresources, 2017, 12(2), 3043-3056 [16] qian s., zhang f., liu b., ren h.*, tong g.l. polyacrylate-based water-absorbent hydrogels prepared with lignin-related compounds: process conditions and performance, bioresources, 2017, 12(3), 6607-6617 [17] zhu l.l., liu h.q., qian s., dai h.q., ren h.* improvement of the physical properties of papersheet-lignophenol composites prepared using a facile impregnation technique, bioresources, 2017, 12(4), 8058-8067 [18] xu d.l., qian s., zhang f., tong g.l., ren h.* preparation of composite films of methacryloyl-modified lignocresol and polylactic acid, bioresources, 2018, 13(1), 740-751 [19] zhang f., ren h.*, tong g.l., omori s. attempt to produce biodiesel from the extracts of sumac (rhus typhina) fruit clusters. cellulose chemistry and technology, 2018, 52(1-2), 75-79 [20] ren h.*, zhu l.l. comparison of the structural characterization of lignophenols and alkaline lignins before and after methylolation. wood science and technology, 2018, 52(4), 1133-1151 [21] ren h., tian w.y., shu f., xu d.l., fu c.x., zhai h.m.* structural characterization of lignocresols from transgenic and wild-type switchgrass. polymers, 2018, 10, 727; doi:10.3390/polym10070727 [22] wu z.y., ren h., xiong w.d., roje s., liu y.c., su k.l., fu c.x.* methylenetetrahydrofolate reductase modulates methyl metabolism and lignin monomer methylation in maize. journal of experimental botany, 2018, 69 (16), 3963-3973 [23] zhao j., ren h.*, xu d.l., omori s. preparation of polyuronic acid by acetobacter xylinum. bioresources, 2018, 13(4), 8646-8652 [24] zhu l.l., feng z., xu d.l., fang g.g., ren h.*, structural analysis of poplar and masson pine lignocresols and comparison of their bovine serum albumin adsorption characteristics, tappi journal, 2019, 19(1), 31-43 [25] zhang h.n., ren h.*, qian s., zhai h.m., effects of different lignins on absorption properties and pore structure of polyacrylic acid resin, wood science and technology, 2019, 53(5), 1001-1004 [26] xu y.r., guo l.f., zhang h.n., zhai h.m., ren h.*, research status, industrial application demand and prospects of phenolic resin, rsc advances, 2019, 9, 28924-28935 [27] feng z., liu q., zhang h.n., xu d.l., zhai h.m., ren h.*, adsorption of bovine serum albumin on the surfaces of poplar lignophenols, international journal of biological macromolecules, 2020, 158, 290-304 [28] xu y.r., wang p.f., xue s.w., kong f.g., ren h.*, zhai h.m., green biorefinery — the ultra-high hydrolysis rate and behavior of populus tomentosa hemicellulose autohydrolysis under moderate subcritical water conditions, rsc advances, 2020, 10, 18908-18917. [29] zhang h.n., zhu l.l., xue s.w., zhao j., ren h.*, zhai h.m., preparation of high oil absorption microfiber cryogels by mechanical method, wood science and technology, 2020,54(5):363-1384. [30] shen r.j., xue s.w., xu y.r., liu q., feng z., ren h.*, zhai h.m., kong f.g., research progress and development demand of nanocellulose reinforced polymer composites, polymers, 2020, 12(9),2113. [31] zhu l.l., xue s.w., ren h.*, zhao j., zhai h.m., kong f.g., effects of lignin content and acid concentration on the morphology, scale and stability of nanocellulose prepared by alkaline hydrogen peroxide mechanical pulp, nordic pulp & paper research journal, 2021, 36(1),125-138. [32] ma q.z., li z.y., zhai h.m.*, ren h.* formation of high carbohydrate and acylation condensed lignin from formic acid-acetic acid-h2o biorefinery of corn stalk rind, industrial crops & products, 2021,161: 113165. [33] zhang h.n., ren h.*, zhai h.m.*analysis of phenolation potential of spruce kraft lignin and construction of its molecular structure model, industrial crops & products, 2021, 167: 113506. [34] ma q.z., wang l.z., zhai h.m.*, ren h.* lignin dissolution model in formic acid–acetic acid–water systems based on lignin chemical structure, international journal of biological macromolecules, 2021, 182: 51-58. [35] wei j.h., wang l.z., zhai s.c., zhai h.m., ren h.* depolymerization behaviors of naked oat stem cell wall during autohydrolysis in subcritical water, industrial crops & products, 2021, 170: 113679. [36] zhao h., tao w.j., gu h.m., guo l.f., han m., zhai h.m., ren h.* evaluation of mulberry branch waste as raw material for nanocellulose synthesis: effects of the synthesis method on product properties, nordic pulp & paper research journal, 2021, 36(4) : [37]liu q., zhang h.n., ren h.*, zhai h.m. structure analysis of light-colored separated lignin (lignocresol) and its antioxidant properties, international journal of biological macromolecules, 2022, 197: 169-178 [38] zhang h.n., zhao h., yang y., ren h.*, zhai h.m.* a novel spectroscopic method for quantitating lignin in lignocellulosic biomass based on licl/dmso completely dissolved solution, green chemistry, 2022, doi: 10.1039/d1gc04257b [39] zhao h., tao w.j., gu h.m., guo l.f., han m., zhai h.m., ren h.* evaluation of mulberry branch waste as raw material for nanocellulose synthesis: effects of the synthesis method on product properties, nordic pulp & paper research journal, 2021, 36(4) : 671-681 [40] zhao h., zhang h.n., ren h.*, zhai h.m. optimized preparation of spruce kraft lignin/zno composites and their performance analysis in polyurethane films, international journal of biological macromolecules, 2022, 209: 1465-1476 [41] wei j.h., ren h.*, zhai h.m., zhai s.c. depolymerization behaviors of naked oat stem during autohydrolysis in mild subcritical water ii: correlative changes in tissue structure, cell morphology, and chemical composition. industrial crops & products, 2022, 187: 115481. [42] liu q., xu y.r., kong f.g., ren h.*, zhai h.m. synthesis of phenolic resins by substituting phenol with modified spruce kraft lignin. wood science and technology, 2022,56(5):1527-1549. [43] wang y., huang j., ma p., guo l.f, zhao h., zhai h.m., ren h. effect of cellulose fiber graft copolymerization with glycidyl methacrylate on the papermaking process retention and drainage aid performance. nordic pulp & paper research journal, 2022, 37(4):657-664. [44] zhang h.n., liu q., ren h.*, zhai h.m. structural comparison of different isolated eucalyptus lignin and analysis of its interaction mechanism with bovine serum albumin solution under qcm-d. holzforschung, 2023, 77(6): 437-452. [45] wei j.h., zhang h.n., zhai s.c., ren h., zhai h.m. effect and control of energy input on tissue and cell dissociation and chemical depolymerization in pure subcritical water autohydrolysis of naked oat stem. green chemistry, 2023, 25(15): 5968-5978. [46] zhao h., zhu y.c., zhang h.n, ren h., zhai h.m. uv-blocking composite films containing hydrophilized spruce kraft lignin and nanocellulose: fabrication and performance evaluation. international journal of biological macromolecules, 2023, 242(3): 124946. [47] yuan j.b., zhang h.n., zhao h., ren h., zhai h.m. study on dissociation and chemical structural characteristics of areca nut husk. molecules, 2023, 28(3): 1513. [48] yi c.f., yuan t.z., ren h., xiao h.n., zhai, h.m. fabrication of food-safe, degradable and high-barrier air frying paper by chitosan, zein and lcnf coatings. cellulose, 2023, 30(4): 2441-2452. [49] yi c.f., yuan t.z., xiao h.n., ren h., zhai, h.m. hydrophobic-modified cellulose nanofibrils (cnfs)/chitosan/zein coating for enhancing multi-barrier properties of heat-sealable food packaging materials. colloid and surfaces a—physicochemical and engineering aspects, 2023, 666: 131245. [50] zhu y.c., zhang h.n., ding shuai, ren h., zhai h.m. cellulose paper based material: an efficient strategy of adjustable adsorption and enriched photodegradation toward multitasking environment remediation. separation and purification technology, 2024, 330, 125365. [51] ding s., zhu y.c., zhang h.n., fu y.j., ren h., zhai h.m. polymerized pei-modified lignin polyphenolic materials by acid hydrolysis-phase separation for removal of cr (vi) from industrial wastewater. international journal of biological macromolecules, 2024, 256: 128358. [52] zhang h. n, zhu y. c, fu t. t, hao c, huang y, ren h*, yan n*. zhai h. m, robust and ultra-tough lignocellulosic organogel with zipper-like sliding noncovalent nanostructural design: towards next-generation bio-derived. chemical engineering journal 485 (2024) 150105. [53] jiang l, zhu y. c, wei j. h, ren h*, zhai h. m, solubilization and structural changes of lignin in naked oat stems during subcritical water autohydrolysis, international journal of biological macromolecules 265 (2024) 130911. [54] liu z.l., cao y.f.*, wang z.g., ren h., amidon e.t., lai y.z. the utilization of soybean straw. і. fiber morphology and chemical characteristics. bioresources, 2015, 10(2), 2266-2280
[55] liu z.l., cao y.f.*, wang z.g., ren h., amidon e.t., lai y.z. the utilization of soybean straw. іі. dissolution®eneration of soybean straw in licl/dmso. bioresources, 2015, 10(2), 2305-2317 [56] liu z.l., meng l.k., chen j.q., cao y.f.*, wang z.g., ren h. the utilization of soybean straw. ш: isolation and characterization of lignin from soybean straw. biomass&bioenergy, 2016, 94, 12-20 [57] meng x., geng w.h., ren h., jin y.c.*, chang h.m., and jameel h., enhancement of enzymatic saccharification of poplar by green liquor pretreatment, bioresources, 2014, 9(2): 3236-3247 [58] chen j.x.*, pan l., xie j., wu g., ren h., wang y., pyrolysis volatiles and environmental impacts of printing paper in air, cellulose, 2014, 21, 2871-2878 [59] pan l., chen j.x.* , wan c.f., ren h., zhai h.m., zheng j.j. investigating the environmental impact of pyrolysis volatiles of printing paper under a nitrogen atmosphere, cellulose chemistry and technology, 2015, 49(9-10), 863-871 [60] wang c.j., chen c., ren h., yang y.q., dai h.q., polyethyleneimine addition for control of dissolved and colloidal substances: effects on wet-end chemistry, bioresources, 2016,11(4),9756-9770 [61] zhang f., ren h., tong g.l., deng y.l., ultra-lightweight poly (sodium acrylate) modified tempo-oxidized cellulose nanofibril aerogel spheres and their superabsorbent properties, cellulose,2016, 23(6), 2665-3676 [62] zhang f., ren h., dou j., tong g.l., deng y.l., cellulose nanofibril based-aerogel microreactors: a high efficiency and easy recoverable w/o/w membrane separation system, scientific reports, 2017,7, 40096 [63] zhang f., ren h., shen l.l., tong g.l., deng y.l., micro-nano structural engineering of filter paper surface for high selective oil-water separation, cellulose, 2017, 24(7), 2913-2924 [64] feng n.j., guo l.f., ren h., xie y.m., jiang z.h., ek monica, zhai h.m., changes in chemical structures of wheat straw auto-hydrolysis lignin by 3-hydroxyanthranilic acid as a laccase mediator, international journal of biological macromolecules, 2019, 122, 210-215 [65] tao w.j., guo l.f., meng a.j., wang l.z., ren h., zhai h.m., effects of xylanase pretreatment on the quality of refiner mechanical mulberry branch fibers, advances in polymer technology, 2019, 6252013, [66] guo l.f., meng a.j., wang l.z., huang j., wang x.j., ren h., zhai h.m., er m., improving the compatibility, surface strength, and dimensional stability of cellulosic fibers using glycidyl methacrylate grafting, journal of materials science, 2020, doi.org/10.1007/s10853-020-04932-9 [67] 任浩*,船岡正光.竹材木素酚对牛血清蛋白吸附和解吸特点的研究[j].纤维素科学与技术,2014,22(2),1-7 [68] 戴歆,任浩*,翟华敏,刘祝兰,曹云峰.相分离条件下楠竹碱木素改性产物的集聚态研究[j].纤维素科学与技术,2014,22(2),14-21 [69] 戴歆, 刘祝兰,任浩*.植物纤维与工程塑料复合的研究现状及展望[j].中国造纸学报,2014,29(3),54-58 [70] 戴歆, 刘波,钱爽,任浩*,刘鹤. 浸渍慈竹木质素酚对纸张强度性能的影响[j].中国造纸学报,2015,30(2),29-33 [71] 钱爽, 戴歆,任浩*,刘波,刘鹤.慈竹木质素酚与聚羟基丁酸酯制膜性能研究[j].中国造纸学报,2015,30(2),39-44 [72] 刘波, 钱爽,陈飞,戴歆,任浩*. 生物质基金属离子吸附材料的开发现状及应用前景[j].纤维素科学与技术,2015,23(3),61-68 [73] 杨华,戴歆,任浩*.毛竹木质素酚与碱木素在羟甲基化改性上的比较研究[j].中华纸业,2015,36(24),22-27 [74] 戴歆,任浩*. 木质素酚复合纸张的制备及性能表征[j].中华纸业,2015,36(24),28-32 [75] 钱爽,任浩*. 聚丙烯纤维在聚3-羟基丁酸酯与木素酚复合膜中的改性作用研究[j].中国塑料, 2015,29(12),34-38 [76] 刘波, 陈飞, 裔力,任浩*. 豆杆和毛竹碱木素的逐级分离及性状表征[j].中国造纸学报, 2016,31(1),37-40 [77] 钱爽,任浩*. 木质素与热塑性塑料共混的研究现状及趋势[j].中国塑料,2016,30(6),1-6 [78] 钱爽,刘波,任浩*. 纤维素接枝甲基丙烯酸丁酯制备吸油材料的探讨[j].纤维素科学与技术,2016,24(4),25-32 [79] 戴歆,任浩*. 木质素酚在纤维纸张表面层层自组装的研究[j].中华纸业,2016,37(16),55-58 [80] 李丹,钱爽,张通,任浩*. 浒苔纤维在改善纸张物理性能上的探讨[j].纤维素科学与技术,2017, 25(1), 32-38 [81] 朱璐璐,刘汗青,钱爽,吴倩,任浩*. 乙酰化前后木质素对甲酚与聚乳酸复合成膜性质影响的比较[j]. 中华纸业,2017, 38(4),27-31 [82] 刘汗青,朱璐璐,钱爽,任浩*. 相分离条件下能源草柳枝稷的分离特性研究[j].中华纸业,2017, 38(4),38-42 [83] 徐栋梁,任浩*. 木质素对纤维素酶水解抑制作用的研究进展与展望[j].中华纸业,2017, 38(20),19-24 [84] 徐栋梁,任浩*,钱爽,郑丽平.甲基丙烯酰氯改性木质素酚共混聚乳酸制备复合膜的研究[j].中国造纸学报,2017, 32(4),32-36 [85] 钱爽,任浩*. 木质素参与的聚丙烯酸高吸水树脂的制备及性能[j].林产化学与工业,2018, 38(2),21-28 [86] 杨艳,任浩,翟华敏*. licl/dmso溶剂体系中麦草溶解性能的评价方法[j].林产化学与工业,2018, 38(4),9-12 [87] 任浩,杨艳,翟华敏*. 机械力与碱处理对不同木质纤维在licl/dmso溶剂体系中溶解性能的影响比较[j].纤维素科学与技术,2018, 26(3), 9-15 [88] 张浩楠,赵瑾,徐栋梁,任浩*. 二维核磁谱对木质素酚与磨木木质素结构的对照解析[j].纤维素科学与技术,2018, 26(4), 9-18 [89] 徐雁茹,张浩楠,任浩*. 酚醛树脂的研究现状、工业化应用需求及展望[j].中国胶黏剂,2019,28(9), 54-62. [90] 赵辉,徐雁茹,任浩*.高替代率木质素酚醛树脂在胶合板中的应用性能比较[j],林产化学与工业,2022, 42(4),75-80. [91] 王丽珍,王俊跃,任浩,翟华敏*.分级法研究脱籽向日葵的细胞形态和化学成分[j]. 林产化学与工业,2022,42(2),25-30. [92] 欧阳琛,沈人杰,陈心茹,等. 静电喷雾法制备木质素微纳颗粒[j]. 林产化学与工业,2023,43(5):89-94. [93] 欧阳琛,沈人杰,陈心茹,等. 聚乳酸共混木质素静电纺丝特性与材料性能[j]. 纤维素科学与技术,2022,30(3):1-10. [94] 王宇,黄军,翟华敏,等. 多胺型纤维素基螯合纤维的合成工艺与结构表征[j]. 林产化学与工业,2023,43(4):81-89. 二、授权发明专利 1、一种以麦草或麦草纤维为原料制备羧甲基纤维素的方法 专利号:zl 201110129687.5 2、一种香肠制造业肠衣废弃物的销毁方法 专利号:zl 201210337387.0 3、一种以粗硫酸盐皂为原料制备生物柴油的方法 专利号:zl 201310124332.6 4、一种用生物聚合法制备水溶性聚糖醛酸的方法 专利号:zl 201510460833.0 5、一种聚丙烯酸类吸水树脂的制备方法 专利号:zl 201611213804.5 6、超声波雾化法制备纤维素纳米纤维气凝胶微球的工艺 专利号:zl 201610252156.8 7、麦草浆及其制备方法、应用及调节cmc取代度的方法 专利号:zl 201811432220.6 8、一种用于木质素酚的铺膜方法及制得的木质素酚膜 专利号:zl 201910041939.5 9、一种不经分离定量测定木质纤维中木质素含量的方法 专利号:zl 201810113336.7 10、一种桦木酸的提取方法 专利号:zl 202010320024.0 11、高吸油性维纳纤维气凝胶、其制备方法及应用 专利号:zl 201910371682.x
|