Correction to: Bioplastic from Renewable Biomass: A Facile Solution for a Greener Environment

Efficient conversion of renewable biomass into value-added chemicals and biofuels is regarded as an alternative route to reduce our high dependence on fossil resources and the associated environmental issues. In this context, biomass-based furfural and levulinic acid (LA) platform chemicals are frequently utilized to synthesize various valuable chemicals and biofuels. In this review, the reaction mechanism and catalytic system developed for the generation of furfural and levulinic acid are summarized and compared. Special efforts are focused on the different catalytic systems for the synthesis of furfural and levulinic acid. The corresponding challenges and outlooks are also observed.

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Clinoptilolite as a natural, active zeolite catalyst for the chemical transformations of geraniol

Reaction Kinetics Mechanisms and Catalysis ◽

10.1007/s11144-021-02027-3 ◽

2021 ◽

Author(s):

Anna Fajdek-Bieda ◽

Agnieszka Wróblewska ◽

Piotr Miądlicki ◽

Jadwiga Tołpa ◽

Beata Michalkiewicz

Keyword(s):

Reaction Time ◽

Nitrogen Adsorption ◽

Carbon Chain ◽

Raw Material ◽

Chemical Transformations ◽

Renewable Biomass ◽

Ft Ir ◽

Catalyst Content ◽

Favorable Conditions ◽

Instrumental Methods

AbstractThis work presented the studies with the natural zeolite—clinoptilolite as the catalyst for the isomerization of geraniol. During the research, it turned out that the studied process is much more complicated, and not only isomerization takes place in it, but also dehydration, oxidation, dimerization, cyclization and fragmentation of the carbon chain. Geraniol is an organic raw material which can be obtained not only by a chemical synthesis but also from plants (renewable biomass) by distillation or extraction method, for example a source of geraniol can be a plant—geranium. Before catalytic tests clinoptilolite was characterized by the instrumental methods, such as: XRD, porosity studies—nitrogen adsorption at 77 K, SEM, EDXRF, and FT-IR. Gas chromatography analyses showed that the main products of geraniol isomerization process were 6,11-dimethyl-2,6,10-dodecatrien-1-ol and thumbergol. The selectivity of 6,11-dimethyl-2,6,10-dodecatrien-1-ol and thumbergol depended on the temperature, catalyst content and reaction time. These parameters were changed in the following ranges: 80–150 °C (temperature), 5–15 wt% (catalyst content) and 15–1440 min. (reaction time). The most favorable conditions for 6,11-dimethyl-2,6,10-dodecatrien-1-ol and thumbergol obtaining were: temperature 140 ºC, catalyst content 12.5 wt% and reaction time 180 min. At these conditions, the conversion of geraniol amounted to 98 mol%, and the selectivities of 6,11-dimethyl-2,6,10-dodecatrien-1-ol and thumbergol amounted to 14 and 47 mol%, respectively.

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Nb2C MXene assisted CoNi bimetallic catalysts for hydrogenolysis of aromatic ethers

Sustainable Energy & Fuels ◽

10.1039/d0se01532f ◽

2021 ◽

Author(s):

Sen-Wang Wang ◽

Zhen-Hong He ◽

Jian-Gang Chen ◽

Kuan Wang ◽

Zhong-Yu Wang ◽

...

Keyword(s):

Bimetallic Catalysts ◽

Precious Metal ◽

Renewable Biomass ◽

Biomass Resources

Hydrogenolysis of biomass-derived lignin sources is highly important for the conversion of renewable biomass resources to biofuels. However, lots of developed catalysts suffer from the drawbacks of expensive precious metal...

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Renewable Biomass Utilization: A Way Forward to Establish Sustainable Chemical and Processing Industries

Clean Technologies ◽

10.3390/cleantechnol3010014 ◽

2021 ◽

Vol 3 (1) ◽

pp. 243-259

Author(s):

Yadhu N. Guragain ◽

Praveen V. Vadlani

Keyword(s):

Fossil Fuels ◽

Process Intensification ◽

Raw Material ◽

Biomass Composition ◽

Biomass Feedstocks ◽

Renewable Biomass ◽

Sustainability Criteria ◽

Biomass Component ◽

Biomass Resources ◽

Multiple Challenges

Lignocellulosic biomass feedstocks are promising alternatives to fossil fuels for meeting raw material needs of processing industries and helping transit from a linear to a circular economy and thereby meet the global sustainability criteria. The sugar platform route in the biochemical conversion process is one of the promising and extensively studied methods, which consists of four major conversion steps: pretreatment, hydrolysis, fermentation, and product purification. Each of these conversion steps has multiple challenges. Among them, the challenges associated with the pretreatment are the most significant for the overall process because this is the most expensive step in the sugar platform route and it significantly affects the efficiency of all subsequent steps on the sustainable valorization of each biomass component. However, the development of a universal pretreatment method to cater to all types of feedstock is nearly impossible due to the substantial variations in compositions and structures of biopolymers among these feedstocks. In this review, we have discussed some promising pretreatment methods, their processing and chemicals requirements, and the effect of biomass composition on deconstruction efficiencies. In addition, the global biomass resources availability and process intensification ideas for the lignocellulosic-based chemical industry have been discussed from a circularity and sustainability standpoint.

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Biocatalysis and biomass conversion: enabling a circular economy

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2019.0274 ◽

2020 ◽

Vol 378 (2176) ◽

pp. 20190274 ◽

Cited By ~ 2

Author(s):

Roger A. Sheldon

Keyword(s):

Circular Economy ◽

Biomass Conversion ◽

Raw Material ◽

Liquid Fuels ◽

Waste Biomass ◽

Renewable Biomass ◽

Precious Metal Catalysts ◽

Mitigate Climate Change ◽

Forestry Residues ◽

The Right

This paper is based on a lecture presented to the Royal Society in London on 24 June 2019. Two of the grand societal and technological challenges of the twenty-first century are the ‘greening' of chemicals manufacture and the ongoing transition to a sustainable, carbon neutral economy based on renewable biomass as the raw material, a so-called bio-based economy. These challenges are motivated by the need to eliminate environmental degradation and mitigate climate change. In a bio-based economy, ideally waste biomass, particularly agricultural and forestry residues and food supply chain waste, are converted to liquid fuels, commodity chemicals and biopolymers using clean, catalytic processes. Biocatalysis has the right credentials to achieve this goal. Enzymes are biocompatible, biodegradable and essentially non-hazardous. Additionally, they are derived from inexpensive renewable resources which are readily available and not subject to the large price fluctuations which undermine the long-term commercial viability of scarce precious metal catalysts. Thanks to spectacular advances in molecular biology the landscape of biocatalysis has dramatically changed in the last two decades. Developments in (meta)genomics in combination with ‘big data’ analysis have revolutionized new enzyme discovery and developments in protein engineering by directed evolution have enabled dramatic improvements in their performance. These developments have their confluence in the bio-based circular economy. This article is part of a discussion meeting issue ‘Science to enable the circular economy'.

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Development of Four Unit Processes for Biobased PLA Manufacturing

ISRN Polymer Science ◽

10.5402/2012/938261 ◽

2012 ◽

Vol 2012 ◽

pp. 1-6 ◽

Cited By ~ 4

Author(s):

Chae Hwan Hong ◽

Si Hwan Kim ◽

Ji-Yeon Seo ◽

Do Suck Han

Keyword(s):

Lactic Acid ◽

Ring Opening ◽

Lactic Acid Production ◽

Scale Up ◽

Catalyst System ◽

Ring Opening Polymerization ◽

Acid Fermentation ◽

Manufacturing Method ◽

Renewable Biomass ◽

Microbial Productivity

Polylactide (PLA), which is one of the most important biocompatible polyesters that are derived from annually renewable biomass such as corn and sugar beets, has attracted much attention for automotive parts application. The manufacturing method of PLA is the ring-opening polymerization of the dimeric cyclic ester of lactic acid, lactide. For the stereocomplex PLA, we developed the four unit processes, fermentation, separation, lactide conversion, and polymerization. Fermentation of sugars to D-lactic acid is little studied, and its microbial productivity is not well known. Therefore, we investigated D-lactic acid fermentation with a view to obtaining the strains capable of producing D-lactic acid, and we got a maximum lactic acid production 60 g/L. Lactide is prepared by a two-step process: first, the lactic acid is converted into oligo(lactic acid) by a polycondensation reaction; second, the oligo(lactic acid) is thermally depolymerized to form the cyclic lactide via an unzipping mechanism. Through catalyst screening test for polycondensation and depolymerization reactions, we got a new method which shortens the whole reaction time 50% the level of the conventional method. Poly(L-lactide) was obtained from the ring-opening polymerization of L-lactide. We investigated various catalysts and polymerization conditions. Finally, we got the best catalyst system and the scale-up technology.

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ASSESSMENT OF ECOLOGICAL AND ECONOMIC EFFICIENCY OF COMPOSITE FUEL PRODUCTION FROM THE PEAT AND BIOMASS

Nature Management ◽

10.47612/2079-3928-2021-1-207-220 ◽

2021 ◽

pp. 207-220

Author(s):

Aleh I. Rodzkin ◽

Evgenija V. Chernenok ◽

Vasilij M. Sivko ◽

Viatcheslav A. Rakovitch

Keyword(s):

Biomass Production ◽

Economic Efficiency ◽

Calorific Value ◽

Cereal Crops ◽

Fuel Production ◽

Renewable Biomass ◽

Prime Cost ◽

Wood Residues ◽

Composite Fuel ◽

Feedstock Production

The goal of investigation was assessment of environmental impact and economic efficiency of composite briquette production on the base of peat and renewable biomass. Biomass for composite briquettes was obtained from straw (cereal crops and rape) and wood residues (sawdust, chips) Experimental composite briquette were produced from the mixture of peat and biomass in relation to – 25 : 75, 50 : 50, 75 : 25. The technological cards of biomass feedstock production for 6 variants were developed. Technological cards were used for calculation of emission into the atmosphere during life cycle of biomass production and prime cost of biomass. The lowest volume of gas (SO2, NOx, CO2) and particulate matter (PM) emission was installed for biomass production from the sawdust. The highest volume of emission was installed for production of biomass from the straw with pressing it in standard bale. The volume of CO2 emission for the sawdust production was 6 kg per ton of biomass and for the standard bale of straw was 19 kg per ton of biomass. Prime cost of sawdust production (lowest) was 11 belarusian rubles per ton of biomass, for the wood chips was 19 rubles per ton and for the straw varied from 26 to 33 rubles per ton in depend of technology. It was installed that growth of biomass rate in composite briquette had a good influence on number of basic fuel characteristics (contents of ash, sulfur and moisture). The variation of calorific value of briquette was not significant in depend of biomass contents. In accordance with assessment of all characteristics the better briquettes was obtained from the peat and sawdust.

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Ultra-refining for the production of long-term highly pH-stable lignin nanoparticles in high yield with high uniformity

Green Chemistry ◽

10.1039/d1gc03525h ◽

2021 ◽

Author(s):

Braz de Souza Marotti ◽

Valdeir Arantes

Keyword(s):

High Yield ◽

Renewable Biomass ◽

High Uniformity

In a bioeconomy, the valorization of lignin beyond its use to generate energy in renewable biomass-based industries is highly attractive and economically critical. However, most of its proposed applications are...

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Rhenium-catalyzed deoxydehydration of renewable biomass using sacrificial alcohol as reductant

Tetrahedron Letters ◽

10.1016/j.tetlet.2017.08.028 ◽

2017 ◽

Vol 58 (39) ◽

pp. 3760-3763 ◽

Cited By ~ 9

Author(s):

Justin Gossett ◽

Radhey Srivastava

Keyword(s):

Renewable Biomass

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