Archive for the ‘实验室活动’ Category

光大交流Visiting Everbright Environment (Group) Co., Ltd (Nanjing) for Collabration

星期四, 7月 14th, 2022

光大交流Visiting Everbright Environment (Group) Co., Ltd (Nanjing) for Collabration

On July 7, 2022, as invited by Dr. Jingwei Wu from China Everbright Environment (Group) Co., Ltd. (Nanjing), Prof. Zhen Fang led biomass group (Drs. Lujiang Xu, Wei Chen, Shuai Gao, Chengyu Dong and Huan Zhang) visited China Everbright Environment (Group) Co., Ltd. for technology exchanges in the treatment of wastes for further collabration in R&D.

In the Exhibition Hall, Dr. Xiaoyu Zheng (Director of the Comprehensive Institute of Everbright Environment Group Technology Research Institute) introduced the development history of Everbright Environment in three major fields of environment, resources and energy, including R&D and commercial plants for waste power generation and co-processing, biomass power generation, hazardous waste and solid waste disposal, environmental restoration, sewage treatment, reclaimed water reuse, water supply, comprehensive water environment management, resource recycling, and equipment manufacturing.

Later, Prof. Zhen Fang gave a lecture on “Pretreatment and hydrolysis of lignocellulosic Biomass for Biorefineries”. He briefly introduced the pretreatment and hydrolysis of lignocelluloses (enzymatic, catalytic and fast hydrolyses), biodiesel production, and synthesis of chemicals and biofuels. Dr. Zheru Shao, Chief Scientist of Everbright International, Director Dr. Xiaoyu Zheng, and the leaders of each group participated in the meeting, and had a lively discussion on the content of Prof. Fang’s lecture. At the same time, Everbright Environment raised current problems and needs for collaborations. It has laid a solid foundation for further in-depth discussion on the technique issues between the two parties.

方真教授一行赴中国光大环境(集团)有限公司开展交流合作

2022年7月7日,方真老师应中国光大环境(集团)有限公司武京伟博士邀请,带领生物质能源研究组(徐禄江副教授、陈伟副教授、高帅副教授、董澄宇博士和张环博士)赴中国光大环境(集团)有限公司开展交流合作,积极探索未来可能的合作方向。

光大环境集团技术研究院综合所所长郑晓宇等带领方真老师参观了光大环境展览厅,并介绍了光大环境的发展历程,在环境、资源、能源三大领域的布局情况,以及垃圾发电及协同处理、生物质发电、危废及固废处置、环境修复、污水处理、中水回用、供水、水环境综合治理、资源循环利用、装备制造等主营业务。

方真老师做了题为“预处理和水解木质纤维素生物质-生物炼制”的专题报告,重点介绍了研究组在木质纤维素的预处理和水解(酶解、催化和快速水解)、生物柴油生产以及化学品和生物燃料的合成等方面的工作。光大国际首席科学家邵哲如、郑晓宇所长、以及各小组组长等参与了交流会,并就方老师报告内容展开热烈讨论,同时也提出了光大环境目前面临的问题和需求,为双方后续进一步深入合作奠定了坚实基础。

Prof. Zhen Fang is listed in “Most Cited Chinese Researchers” in energy for 2015 again

星期五, 3月 4th, 2016

Recently, Elsevier-Scopus  listed Prof. Zhen Fang in “Most Cited Chinese Researchers” in energy for 2015 again after 2014.
继2014年,方真研究员再次进入2015年“中国高被引学者”能源领域榜单(Elsevier-Scopus).
Prof. Zhen Fang (PhDs Eng., McGill; CAU); a researcher in bioenergy; inventor of “fast hydrolysis” process; Editor-in-Chief, Springer Book Series – Biofuels and Biorefineries; Associate Editor, Biotechnology for Biofuels (IF 6.2, Highest IF in Biofuels); and Editorial Advisory Board Members of Biofpr (Biofuels, Bioproducts and Biorefining, IF 4.3) and Energy, Sustainability and Society (a Springer open Journal).

2015年“中国高被引学者榜单”研究数据和技术分析基于全球最大的同行评议学术论文索引摘要数据库(Scopus数据库),该数据库收录来自全球超过5000个出版商、21000种期刊的5500余万条文献索引,覆盖各个学科,并提供各种工具用于追踪、分析和可视化学术研究,通过对客观引用数据的分析,对研究者在世界范围内的影响力进行系统的评价。此次榜单中,来自中国的社会科学、物理、化学、数学、经济等38学科的1744名最具世界影响力的中国学者入选。

http://www.zuihaodaxue.com/Article.jsp?id=WzQpgBmjMtkbcp4LvpaLvG8oNQTgE8)

2014:

11.4%的中国科学院院士是高被引学者

3.7%的中国工程院院士是高被引学者

17.6%的长江学者特聘教授是高被引学者

18.1%的国家杰出青年科学基金获得者是高被引学者

Biomass group was evaluated as the best group for 2015

星期三, 2月 24th, 2016

Biomass group was evaluated as the best group for 2015

Recently, Biomass group was evaluated as best group of Key Laboratory of Tropical Plant

Resources and Sustainable Use of CAS for 2015, and excellent research group of Xishuangbanna Tropical Botanical Garden for 2015.

Congratulations!
生物能源组被评为2015年优秀小组

最近,生物质组被评为2015年度中国科学院热带植物资源和可持续利用重点实验室的最佳小组,以及2015年度西双版纳热带植物园的优秀研究小组。

2015excellent group

超顺磁酸碱双功能纳米ZrFeOx催化剂的合成及用以生产生物燃料

星期六, 1月 30th, 2016

超顺磁酸碱双功能纳米ZrFeOx催化剂的合成及用以生产生物燃料

酸碱双功能纳米颗粒广泛用来合成生物燃料和高附加值的化学品。特别是磁性纳米金属氧化物,活性高可一锅法生产生物燃料,易于回收和重复利用。

生物能源组与贵州大学联合培养的博士生李虎在导师杨松教授和方真研究员的指导下,通过溶剂热处理和水解缩合的两步法合成酸碱双功能的超顺磁性纳米颗粒。合成的ZrFeOx纳米颗粒大约为12 nm, 中心为Fe3O4纳米颗粒(作为磁核),其外面覆盖了一层0.65 nm厚的ZrO2。ZrFeOx纳米颗粒具有分布良好的酸碱含量(0.39 vs. 0.28 mmol/g),适度的表面积(181 m2/g),孔径(9.8 nm)和较强的磁性(35.4 Am2 kg−1)。ZrFeOx纳米颗粒在乙醇中,进一步用来催化乙酰丙酸乙酯转换为γ戊内酯(GVL): 在230 ºC,反应3小时,GVL产率可高达87.2%。该纳米催化剂与固体酸HY2.6组合,可将糖直接转化为GVL,得到适中产率(约45%)。此外,磁性ZrFeOx纳米颗粒可很方便地由磁铁回收,可进行至少六次的重复利用。

祥情可见:

H Li, Zhen Fang*, S Yang, Direct Conversion of Sugars and Ethyl Levulinate into γ-Valerolactone with Superparamagnetic Acid-Base Bifunctional ZrFeOx Nanocatalysts, ACS Sustainable Chemistry & Engineering, 4(1), 236-246 (2016).
Synthesis of Superparamagnetic Acid−Base Bifunctional ZrFeOx Nanocatalyst for Biomass Conversion

Acid−base bifunctional nanocatalysts can directly on-pot produce biofuels and chemical from biomass. Particularly, some magnetic metal oxides that are active and recyclable.

Mr. Hu Li, a PhD student, co-supervised by Prof. Song Yang (Guizhou University) and Prof. Zhen FANG (Biomass Group, Xishuangbanna Tropical Botanical Garden, CAS) successfully synthesized bifunctional ZrFeOx nanocatalyst for biomass conversions.

In their work, acid-base bifunctional superparamagnetic FeZrOx nanoparticles were synthesized via a two-step process of solvothermal treatment and hydrolysis-condensation, and were further employed to catalyze the conversion of ethyl levulinate (EL) to γ-valerolactone (GVL) using ethanol as both H-donor and solvent. ZrFeO(1:3)-300 nanoparticles (12.7 nm) with Fe3O4 core covered by ZrO2 layer (0.65 nm thickness) having well- distributed acid-base sites (0.39 vs. 0.28 mmol/g), moderate surface area (181 m2/g), pore size (9.8 nm) and strong magnetism (35.4 Am2 kg−1) exhibited superior catalytic performance, giving a high GVL yield of 87.2% at 230 ºC in 3 h. The combination of the nanoparticles with solid acid HY2.6 promoted the direct transformation of sugars to produce GVL in moderate yield (around 45%). Moreover, the nanocatalyst was easily recovered by a magnet for six cycles with an average GVL yield of 83.9% from EL.

The study was published:

H Li, Zhen Fang*, S Yang, Direct Conversion of Sugars and Ethyl Levulinate into γ-Valerolactone with Superparamagnetic Acid-Base Bifunctional ZrFeOx Nanocatalysts, ACS Sustainable Chemistry & Engineering, 4(1), 236-246 (2016).

Presentation1


TEM images of ZrFeOx nanocatalyst

磁性镍锆纳米氧化物,高效催化生物质合成γ戊内酯(GVL)

星期四, 1月 28th, 2016

镍锆纳米氧化物,高效催化生物质合成γ戊内酯GVL
γ戊内酯(GVL)已被确定为一种绿色的和可再生的溶剂,用以提高生物质转化和各种有机反应。它可作为液体燃料,香料和食物的添加剂。更重要的是,GVL可以用来合成汽油和柴油燃料(例如,C8-C18烷烃和2-甲基四氢呋喃)和高价值的化学物质(如1,4-戊二醇,甲基戊酸,离子液体和聚合物)。

生物能源组与贵州大学联合培养的博士生李虎在导师杨松教授和方真研究员的指导下,用共沉淀方法合成了一系列的混合氧化物纳米颗粒。研究发现,在不使用外部氢源的情况下,还原后的磁性镍 – 氧化锆纳米颗粒可直接高效转化生物质衍生物(如乙酰丙酸乙酯,果糖,葡萄糖,纤维二糖和羧甲基纤维素)为GVL。用磁性纳米颗粒Zr5Ni5(< 20纳米)作为催化剂,在200℃下反应3小时,最大GVL产率为95.2%。这些纳米催化剂具备酸碱二重性,对GVL的合成具有协同作用。 此外,磁性Zr5Ni5纳米颗粒可很方便地由磁铁回收,可进行至少五次的重复利用。

近日,文章“H Li, Zhen Fang*, S Yang, Direct Catalytic Transformation of Biomass Derivatives into Biofuel Component γ-Valerolactone with Magnetic NiZr Nanoparticles, 81, 135-142, (2016).” 在国际期刊《ChemPlusChem》发表:  http://onlinelibrary.wiley.com/doi/10.1002/cplu.201500492/abstract
Converting biomass derivatives into biofuel component γ-valerolactone (GVL) with magnetic NiZr nanoparticles

γ-valerolactone (GVL) has been identified as a green and renewable solvent to improve the performance of biomass conversion and various organic reactions, and as an additive suitable for liquid fuels, perfumes and food. More importantly, GVL is able to be employed as a precursor to produce gasoline and diesel fuels (e.g., C8−C18 alkanes and 2-methyltetrahydrofurane) and valuable chemicals such as 1,4-pentanediol and methyl pentenoate, as well as ionic liquids and polymers.

Mr. Hu Li, a PhD student, co-supervised by Prof. Song Yang (Guizhou University) and Prof. Zhen FANG (Biomass Group, Xishuangbanna Tropical Botanical Garden, CAS) successfully synthesized g-valerolactone.

In their work, a series of mixed oxide nanoparticles were prepared by coprecipitation method and characterized by many techniques. NiZr oxide catalysts and their partially reduced magnetic counterparts were highly efficient in direct transformation of biomass derivatives including ethyl levulinate, fructose, glucose, cellobiose and carboxymethyl cellulose into GVL without using external hydrogen source, producing a maximum GVL yield of 95.2% at 200 ºC for 3 h with H2 reduced magnetic Zr5Ni5 nanoparticles (< 20 nm). Acid-base bifunctionality of these nanocatalysts is found to play a synergic role in synthesis of GVL in alcohols, while appropriate control of Ni/Zr molar ratio is able to improve the selectivity towards GVL (~98%), along with high formation rates (up to 54.9 mmol g−1 h−1). Moreover, the magnetic Zr5Ni5 nanoparticles were conveniently recovered by a magnet for five recycles with almost constant activity.

The study entitled “H Li, Zhen Fang*, S Yang, Direct Catalytic Transformation of Biomass Derivatives into Biofuel Component γ-Valerolactone with Magnetic NiZr Nanoparticles, 81, 135-142, (2016).” has been published in ChemPlusChem:  http://onlinelibrary.wiley.com/doi/10.1002/cplu.201500492/abstract

 Presentation1

 Magnetic nanoparticles: Acid-base bifunctional NiZr nanocatalysts with strong magnetism show high activity and reusability in transformation of biomass derivatives including EL, fructose, glucose, cellobiose and carboxymethyl cellulose into γ-valerolactone (GVL) with 95.2% yield and 98% selectivity.