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      Guidelines for performing lignin-first biorefining

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          Abstract

          With these guidelines, we aim to unite the lignin-first biorefining research field around best practices for performing or reporting feedstock analysis, reactor design, catalyst performance, and product yields.

          Abstract

          The valorisation of the plant biopolymer lignin is now recognised as essential to enabling the economic viability of the lignocellulosic biorefining industry. In this context, the “lignin-first” biorefining approach, in which lignin valorisation is considered in the design phase, has demonstrated the fullest utilisation of lignocellulose. We define lignin-first methods as active stabilisation approaches that solubilise lignin from native lignocellulosic biomass while avoiding condensation reactions that lead to more recalcitrant lignin polymers. This active stabilisation can be accomplished by solvolysis and catalytic conversion of reactive intermediates to stable products or by protection-group chemistry of lignin oligomers or reactive monomers. Across the growing body of literature in this field, there are disparate approaches to report and analyse the results from lignin-first approaches, thus making quantitative comparisons between studies challenging. To that end, we present herein a set of guidelines for analysing critical data from lignin-first approaches, including feedstock analysis and process parameters, with the ambition of uniting the lignin-first research community around a common set of reportable metrics. These guidelines comprise standards and best practices or minimum requirements for feedstock analysis, stressing reporting of the fractionation efficiency, product yields, solvent mass balances, catalyst efficiency, and the requirements for additional reagents such as reducing, oxidising, or capping agents. Our goal is to establish best practices for the research community at large primarily to enable direct comparisons between studies from different laboratories. The use of these guidelines will be helpful for the newcomers to this field and pivotal for further progress in this exciting research area.

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          Most cited references194

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          Features of promising technologies for pretreatment of lignocellulosic biomass.

          N. Mosier (2005)
          Cellulosic plant material represents an as-of-yet untapped source of fermentable sugars for significant industrial use. Many physio-chemical structural and compositional factors hinder the enzymatic digestibility of cellulose present in lignocellulosic biomass. The goal of any pretreatment technology is to alter or remove structural and compositional impediments to hydrolysis in order to improve the rate of enzyme hydrolysis and increase yields of fermentable sugars from cellulose or hemicellulose. These methods cause physical and/or chemical changes in the plant biomass in order to achieve this result. Experimental investigation of physical changes and chemical reactions that occur during pretreatment is required for the development of effective and mechanistic models that can be used for the rational design of pretreatment processes. Furthermore, pretreatment processing conditions must be tailored to the specific chemical and structural composition of the various, and variable, sources of lignocellulosic biomass. This paper reviews process parameters and their fundamental modes of action for promising pretreatment methods.
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            Catalytic Transformation of Lignin for the Production of Chemicals and Fuels.

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              The catalytic valorization of lignin for the production of renewable chemicals.

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                Author and article information

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                Journal
                EESNBY
                Energy & Environmental Science
                Energy Environ. Sci.
                Royal Society of Chemistry (RSC)
                1754-5692
                1754-5706
                January 26 2021
                2021
                : 14
                : 1
                : 262-292
                Affiliations
                [1 ]Department of Chemical Engineering and Department of Chemistry & Biochemistry
                [2 ]University of California
                [3 ]Santa Barbara
                [4 ]USA
                [5 ]Stratingh Institute for Chemistry
                [6 ]University of Groningen
                [7 ]9747 AG Groningen
                [8 ]The Netherlands
                [9 ]Renewable Resources and Enabling Sciences Center, National Renewable Energy Laboratory
                [10 ]Golden
                [11 ]Center for Bioenergy Innovation
                [12 ]Oak Ridge
                [13 ]Laboratory of Sustainable and Catalytic Processing
                [14 ]Institute of Chemical Sciences and Engineering
                [15 ]École Polytechnique Fédérale de Lausanne (EPFL)
                [16 ]CH-1015 Lausanne
                [17 ]Switzerland
                [18 ]U.S. Department of Energy Great Lakes Bioenergy Research Center
                [19 ]University of Wisconsin-Madison
                [20 ]Madison
                [21 ]Department of Chemical Engineering
                [22 ]Imperial College London
                [23 ]London SW7 2AZ
                [24 ]UK
                [25 ]MIT
                [26 ]Cambridge
                [27 ]Department of Organic Chemistry
                [28 ]Stockholm University
                [29 ]SE-106 91 Stockholm
                [30 ]Sweden
                [31 ]Center for Sustainable Catalysis and Engineering
                [32 ]KU Leuven
                [33 ]3001 Leuven
                [34 ]Belgium
                [35 ]State Key Laboratory of Catalysis
                [36 ]Dalian National Laboratory for Clean Energy
                [37 ]Dalian Institute of Chemical Physics
                [38 ]Chinese Academy of Sciences
                [39 ]Dalian
                Article
                10.1039/D0EE02870C
                9d0774a4-a8e8-4310-977b-571ac3d53831
                © 2021

                http://creativecommons.org/licenses/by/3.0/

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