Will Zeolite‐Based Catalysis be as Relevant in Future Biorefineries as in Crude Oil Refineries?

Transition from petroleum‐ to biomass‐based fuel economy will require new conversion strategies. In a petroleum refinery, particular hydrocarbon fractions from crude oil are catalytically converted into high‐grade fuels. Certain zeolite catalysts are performing exceptionally well. Unlike petroleum fractions, biomass‐derived compounds have a high oxygen content requiring low‐temperature catalytic aqueous phase processes for selective conversion and stability of zeolite catalysts in hot liquid water. It will be shown that recent developments in zeolite synthesis and modification allow adapting zeolite properties to achieve selective conversion of biomass compounds/fractions as well.     

生物质利用新途径:多元醇催化合成可再生燃料和化学品

日益严重的全球性能源和环境问题促使开发利用可再生的生物质资源成为当前研究的一个热点。本文概述了生物质基多元醇合成燃料和化学品来实现生物质转化利用的一些最新进展,特别是集中介绍了甘油和山梨醇等多元醇催化水相重整合成氢气和液体烃等燃料、催化选择氢解和氧化合成高附加值化学品或化学中间体等方面的进展,分析了存在的问题和可能的解决措施以及今后的发展趋势,指出生物质基多元醇将成为今后合成可再生燃料和化学品的新型平台分子。     

生物质利用新途径:多元醇催化合成可再生燃料和化学品

日益严重的全球性能源和环境问题促使开发利用可再生的生物质资源成为当前研究的一个热点.本文概述了生物质基多元醇合成燃料和化学品来实现生物质转化利用的一些最新进展,特别是集中介绍了甘油和山梨醇等多元醇催化水相重整合成氢气和液体烃等燃料、催化选择氢解和氧化合成高附加值化学品或化学中间体等方面的进展,分析了存在的问题和可能的解决措施以及今后的发展趋势,指出生物质基多元醇将成为今后合成可再生燃料和化学品的新型平台分子.     

Polyoxometalates as efficient catalysts for transformations of cellulose into platform chemicals

Efficient utilisation of renewable biomass resources, particularly lignocellulosic biomass, for the production of chemicals and fuels has attracted much attention in recent years. The catalytic conversion of cellulose, the main component of lignocellulosic biomass, selectively into a platform chemical such as glucose, 5-hydroxymethyl furfural (HMF), sorbitol or gluconic acid under mild conditions is the most desirable route. Acid catalysis plays a crucial role in the conversion of cellulose via the cleavage of its glycosidic bonds. Owing to their unique features such as strong acidity, water-tolerance, low corrosiveness and recoverability, polyoxometalates have shown promising performances in transformations of cellulose into platform chemicals both in homogeneous and heterogeneous systems. This article highlights recent studies on polyoxometalates and polyoxometalate-based bifunctional catalysts or catalytic systems for the selective conversions of cellulose and cellobiose, a model molecule of cellulose, into platform chemicals.     

Biocatalysis and Biomass Conversion in Alternative Reaction Media

In this Minireview, the state of the art in the use of ionic liquids (ILs) and deep eutectic solvents (DESs) as alternative reaction media for biocatalytic processes and biomass conversion is presented. Initial, proof‐of‐concept studies, more than a decade ago, involved first‐generation ILs based on dialkylimidazolium cations and non‐coordinating anions, such as tetrafluoroborate and hexafluorophosphate. More recently, emphasis has switched to more environmentally acceptable second‐generation ILs comprising cations, which are designed to be compatible with enzymes and, in many cases are derived from readily available, renewable resources, such as cholinium salts. Protic ionic liquids (PILs), prepared simply by mixing inexpensive amines and acids, are particularly attractive from both an environmental and economic viewpoint. DESs, prepared by mixing inexpensive salts with, preferably renewable, hydrogen‐bond donors such as glycerol and amino acids, have also proved suitable reaction media for biocatalytic conversions. A broad range of enzymes can be used in ILs, PILs and DESs, for example lipases in biodiesel production. These neoteric solvents are of particular interest, however, as reaction media for biocatalytic conversions of substrates that have limited solubility in common organic solvents, such as carbohydrates, nucleosides, steroids and polysaccharides. This has culminated in the recent focus of attention on their use as (co)solvents in the pretreatment and saccharification of lignocellulose as the initial steps in the conversion of second‐generation renewable biomass into biofuels and chemicals. They can similarly be used as reaction media in subsequent conversions of hexoses and pentoses into platform chemicals.     

常压连续反应性萃取法由预处理生物质制备乙酰丙酸

采用双相联系流反应性萃取技术实现常压下小麦秸秆向乙酰丙酸的转化,其中生物质在水相中完成降解,形成乙酰丙酸,而后比水密度大的有机相作为乙酰丙酸的萃取相,把生成的乙酰丙酸萃取到有机相,并经过虹吸到收集瓶中,有机相经蒸馏可反复使用,实现了预处理生物质到乙酰丙酸的高效转化,乙酰丙酸最大的产率为30.66%.     

Analytical strategies for chemical characterization of bio‐oil

Bio‐oils, produced by biomass pyrolysis, have become promising candidates for feedstocks of high value‐added chemicals and alternative sources for transportation fuels. Bio‐oil is such a complicated mixture that contains nonpolar hydrocarbons and polar components which cover almost all kinds of organic oxygenated compounds such as carboxylic acids, alcohols, aldehydes, ketones, esters, furfurals, phenolic compounds, sugar‐like material, and lignin‐derived compounds. Comprehensive characterization of bio‐oil and its subfractions could provide insight into the conversion process of biomass processing, as well as its further utilization as transportation fuels or chemical raw materials. This review focuses on advanced analytical strategies on in‐depth characterization of bio‐oil, which is concerned with gas chromatography, high‐resolution mass spectrometry, FTIR spectroscopy and NMR spectroscopy, offering complementary information for previous reviews.     

Bio-refinery as the bio-inspired process to bulk chemicals

This paper describes several examples of knowledge-intensive technologies for the production of chemicals from biomass, which take advantage of the biomass structure in a more efficient way than the production of fuels or electricity alone. The depletion in fossil feedstocks, increasing oil prices, and the ecological problems associated with CO(2) emissions are forcing the development of alternative resources for energy, transport fuels, and chemicals, such as the replacement of fossil resources with CO(2) neutral biomass. Allied with this is the conversion of crude oil products utilizes primary products (ethylene, etc.) and their conversion into either materials or (functional) chemicals with the aid of co-reagents such as ammonia, by various process steps to introduce functionalities such as -NH(2) into the simple structures of the primary products. Conversely, many products found in biomass often contain functionalities. Therefore, it is attractive to exploit this in order to by-pass the use, and preparation of, co-reagents as well as to eliminate various process steps by utilizing suitable biomass-based precursors for the production of chemicals.     

Biofuels and biomass-to-liquid fuels in the biorefinery: catalytic conversion of lignocellulosic biomass using porous materials

At a time when the focus is on global warming, CO(2) emission, secure energy supply, and less consumption of fossil-based fuels, the use of renewable energy resources is essential. Various biomass resources are discussed that can deliver fuels, chemicals, and energy products. The focus is on the catalytic conversion of biomass from wood. The challenges involved in the processing of lignocellulose-rich materials will be highlighted, along with the application of porous materials as catalysts for the biomass-to-liquids (BTL) fuels in biorefineries. The mechanistic understanding of the complex reactions that take place, the development of catalysts and processes, and the product spectrum that is envisaged will be discussed, along with a sustainable concept for biorefineries based on lignocellulose. Finally, the current situation with respect to upgrading of the process technology (pilot and commercial units) will be addressed.     

5-Hydroxymethylfurfural: A key intermediate for efficient biomass conversion

Biomass has been widely accepted as a "zero-emission" energy carrier to take place fossil fuels, while its catalytic conversion is still limited by low efficiency of carbon atoms. Biomass conversion via 5-hydroxymethylfurfural(HMF) as a platform chemical is highly attractive because almost all carbon atoms could be retained in the downstream chemicals under mild reaction conditions. Here we summarize recent fundamental researches and industrial progresses on all involved processes including biomass degradation to hexoses, HMF formation, hydrogenation and oxidation of HMF.     

Highly Efficient Chemical Process To Convert Mucic Acid into Adipic Acid and DFT Studies of the Mechanism of the Rhenium‐Catalyzed Deoxydehydration

The production of bulk chemicals and fuels from renewable bio‐based feedstocks is of significant importance for the sustainability of human society. Adipic acid, as one of the most‐demanded drop‐in chemicals from a bioresource, is used primarily for the large‐volume production of nylon‐6,6 polyamide. It is highly desirable to develop sustainable and environmentally friendly processes for the production of adipic acid from renewable feedstocks. However, currently there is no suitable bio‐adipic acid synthesis process. Demonstrated herein is the highly efficient synthetic protocol for the conversion of mucic acid into adipic acid through the oxorhenium‐complex‐catalyzed deoxydehydration (DODH) reaction and subsequent Pt/C‐catalyzed transfer hydrogenation. Quantitative yields (99 %) were achieved for the conversion of mucic acid into muconic acid and adipic acid either in separate sequences or in a one‐step process.     

呋喃类平台化合物催化转化成可再生化学品和燃料

正随着石油资源的相对贫乏和环境问题的加剧,寻求新的能源和途径来代替传统的化石资源越来越受到人们的关注.生物质在地球上含量丰富、分布广泛、价格较低廉且能够很好的实现碳循环,作为一种可持续和可再生资源,在取代传统的石油产品方面具有很大的潜力,能很好满足社会对燃料和化学品的需求,从而实现由不可再生的石油资源向可再生的生物能源的过渡.植物类生物质的主要成分是碳水化合物即纤维素和木质素,在一定条件下可     

Nanostructured Metal Catalysts for Selective Hydrogenation and Oxidation of Cellulosic Biomass to Chemicals

Conversion of biomass to chemicals provides essential products to human society from renewable resources. In this context, achieving atom‐economical and energy‐efficient conversion with high selectivity towards target products remains a key challenge. Recent developments in nanostructured catalysts address this challenge reporting remarkable performances in shape and morphology dependent catalysis by metals on nano scale in energy and environmental applications. In this review, most recent advances in synthesis of heterogeneous nanomaterials, surface characterization and catalytic performances for hydrogenation and oxidation for biorenewables with plausible mechanism have been discussed. The perspectives obtained from this review paper will provide insights into rational design of active, selective and stable catalytic materials for sustainable production of value‐added chemicals from biomass resources.     

Radical-Mediated Photocatalysis for Lignocellulosic Biomass Conversion into Value-Added Chemicals and Hydrogen: Facts,Opportunities and Challenges

Photocatalytic biomass conversion into high-value chemicals and fuels is considered one of the hottest ongoing research and industrial topics toward sustainable development. In short, this process can cleave C_β−O/C_α−C_β bonds in lignin to aromatic platform chemicals, and further conversion of the polysaccharides to other platform chemicals and H₂. From the chemistry point of view, the optimization of the unique cooperative interplay of radical oxidation species (which are activated via molecular oxygen species, ROSs) and substrate-derived radical intermediates by appropriate control of their type and/or yield is key to the selective production of desired products. Technically, several challenges have been raised that face successful real-world applications. This review aims to discuss the recently reported mechanistic pathways toward selective biomass conversion through the optimization of ROSs behavior and materials/system design. On top of that, through a SWOT analysis, we critically discussed this technology from both chemistry and technological viewpoints to help the scientists and engineers bridge the gap between lab-scale and large-scale production.     

Asymmetric Conjugate Additions and Allylic Alkylations Using Nucleophiles Generated by Hydro‐ or Carbometallation

This Minireview discusses catalytic asymmetric conjugate addition and allylic alkylation reactions where the nucleophiles were generated in situ by hydrometallation or carbometallation. This exciting recent trend in asymmetric catalysis promises to expand the range of transformations available for the rapid and selective assembly of complex, functional molecules for both academic and industrial research. This Minireview aims to serve as a reference for studies reported to date and discusses the current state‐of‐the‐art, scope and limitations of these processes.     

Novel hydrothermal carbonization of cellulose catalyzed by montmorillonite to produce kerogen-like hydrochar

The conversion of cellulose to petroleum-like fuel is a very challenging yet attractive route to developing biomass-to-fuel technology. Many attempts have been made in liquefaction, pyrolysis and gasification of cellulose to produce fuels or intermediate chemicals. Previous studies indicate that these processes are tough. Hence, the present work is concerned with the development of new technologies for the conversion of cellulose into materials which are analogies to the precursor of petroleum. Montmorillonite-catalyzed hydrothermal carbonization of microcrystalline cellulose for the production of kerogen-like hydrochar under mild conditions was investigated. It was revealed that the hydrothermal carbonization of microcrystalline cellulose alone resulted in hydrochar with type III kerogen-like structure, whereas in the presence of montmorillonite, the hydrothermal carbonization of microcrystalline cellulose yielded a hydrochar-mineral complex, of which the isolated organic fraction was oil-prone type II kerogen-like structure. Results suggested that further improved montmorillonite-aided biomass conversion to more oil-prone kerogen-like solid products could be an alternative efficient route to obtain biofuel and chemicals.     

Thermal processing of algal biomass for biofuel production

Concerns over the environment and energy security have led to considerable research efforts into the development of renewable alternatives to fossil-based fuels and chemical from biomass. Algae has been identified as the biomass with great potential for utilization in this regard, due to several advantages algae has over terrestrial plants, such as a higher growth rate and photosynthetic efficiency, better CO₂ sequestration, and the ability to grow in non-arable land with low quality water. Conversion technologies, particularly thermochemical conversion, are actively being researched and developed to produce renewable chemicals and fuels. A major advance in this regard is thermal conversion of whole algal biomass, especially wet processing that can significantly reduce the cost of production. This short review looks at major developments in thermal processing of algal biomass with primary focus on the past two years.     

木质纤维素中C-O键选择性活化和高效转化制化学品

高效转化来源丰富且可再生的木质纤维素制备化学品和燃料对建立可持续发展社会具有重要意义。木质纤维素利用的一条理想途径是将其主要成分纤维素、半纤维素和木质素在温和条件下高选择性地催化转化为关键平台化学品。本文综述了近年报道的有关纤维素、半纤维素和木质素或其模型分子中C–O键选择性活化生成葡萄糖、葡萄糖衍生物(包括葡萄糖苷、六元醇和葡萄糖酸)、木糖、阿拉伯糖和芳香化合物的新催化剂和新策略,阐述了决定催化性能的关键因素。本文还讨论了相关反应机理以深入理解C–O键选择性活化。纤维素由葡萄糖单元通过β-1,4-糖苷键连接而成,通过水解反应,选择性切断这些糖苷键可以获得葡萄糖或其低聚物。鉴于葡萄糖在水热条件下不稳定,发展纤维素温和条件下水解的酸催化剂至关重要。众多研究表明,均相酸催化剂(如无机酸,杂多酸等)具有强Br?nsted酸,在该水解反应中显示高的催化活性。另一方面,拥有强酸性基团-SO3H的固体酸也表现出优异的水解糖苷键性能,但是-SO3H官能团易于流失,限制了这类固体酸催化剂的循环使用。最近研究显示,一些催化剂尤其是碳材料上引入能够与纤维素形成氢键的官能团时,其催化纤维素水解性能显著增强。设计合成这类具备酸性位和氢键位协同效应的稳定固体酸催化剂是纤维素水解转化的一个颇具前景的研究方向。以醇替代水为溶剂实施纤维素醇解制葡萄糖苷是高效活化糖苷键的有效策略。杂多酸被证实为该醇解反应的高性能催化剂。在相同反应条件下,醇解产物葡萄糖苷较水解产物葡萄糖更为稳定,因此可以获得高的葡萄糖苷收率。开发稳定可重复利用的固体酸催化剂是纤维素醇解的关键。耦合水解与加氢或氧化反应可以直接将纤维素转化为相对稳定且具有广泛用途的多元醇或有机酸。目前已有一系列双功能催化剂被报道,这些催化剂通常组合了具备水解功能的液体酸或固体酸和具备加氢或氧化功能的贵金属或过渡金属(譬如Ru, Pt, Ni和Au)。其中杂多酸盐或含有磺酸官能团的固体酸负载Ru或Au双功能催化剂显示出优异的生成六元醇或葡萄糖酸的催化性能。半纤维素由葡萄糖、甘露糖、木糖、阿拉伯糖、半乳糖等单糖单元通过糖苷键连接而成,糖苷键选择性活化可生成各种单糖混合物。硫酸可以有效水解半纤维素,但是同时也易于催化所生成的单糖深度转化为呋喃及其衍生物。较之硫酸,酸性较弱的有机酸特别是二元羧酸(例如马来酸、草酸等)具有较高的单糖选择性。固体酸如酸性树脂,分子筛等亦可催化半纤维素水解反应,但树脂类催化剂中官能团的流失问题有待解决。木质素是由含甲氧基等取代基的苯丙烷单元通过一系列化学键连接而成的复杂大分子,其芳香单元间包括β-O-4,α-O-4和4-O-5等三种主要连接方式,选择性切断这些C–O键可获得高附加值的芳香化合物。水解和氢解是两类普遍用以活化木质素及其模型化合物C–O键的反应。酸和碱均可催化木质素及其模型化合物水解,但是通常需要苛刻条件获取高转化率。近期研究显示,通过对木质素Cα-OH预氧化,再以HCOOH/HCOONa实施水解反应,可以成功实现温和条件下有机溶剂提取木质素及其模型化合物的高效转化。另一方面,均相金属络合物(如Ni, Fe和Ru)或多相负载型金属催化剂(如Ni, Cu, Mo, Pt, Ru, Pd或Ru等)均可有效催化木质素及其模型化合物中C–O键氢解,获得芳烃化合物。在部分多相催化剂体系中,除C–O键活化断裂外,还伴随芳环深度加氢反应,产生较多环己烷衍生物。因此,设计合成具备氢解功能同时抑制过度加氢功能的催化剂是获得芳烃化合物的关键。     

Fungal glycoside hydrolases for saccharification of lignocellulose: outlook for new discoveries fueled by genomics and functional studies

Genome sequencing of a variety of fungi is a major initiative currently supported by the Department of Energy’s Joint Genome Institute. Encoded within the genomes of many fungi are upwards of 200+ enzymes called glycoside hydrolases (GHs). GHs are known for their ability to hydrolyze the polysaccharide components of lignocellulosic biomass. Production of ethanol and “next generation” biofuels from lignocellulosic biomass represents a sustainable route to biofuels production. However, this process has to become more economical before large scale operations are put into place. Identifying and characterizing GHs with improved properties for biomass degradation is a key factor for the development of cost effective processes to convert biomass to fuels and chemicals. With the recent explosion in the number of GH encoding genes discovered by fungal genome sequencing projects, it has become apparent that improvements in GH gene annotation processes have to be developed. This will enable more informed and efficient decision making with regard to selection and utilization of these important enzymes in bioprocess that produce fuels and chemicals from lignocellulosic feedstocks.     

超薄Ni掺杂ZnIn2S4纳米片用于光催化醇裂解同时制备C-C耦合产物及氢气

光催化析氢技术被认为是解决化石能源紧缺和环境污染问题的有效途径之一.在传统的光解水体系中,析氧半反应因涉及到复杂的四电子转移和O=O双键形成,成为光催化水分解的决速步骤.光生空穴牺牲试剂的引入虽然可以在一定程度上提高体系的光催化效率,但同时造成了光生空穴氧化能力的浪费,且增加了系统成本.相比之下,构建由光催化析氢和选择...