Radicals and molecular products from the gas-phase pyrolysis of lignin model compounds. Cinnamyl alcohol

Khachatryan, Lavrent; Xu, Mengxia; Wu, Angjian; Pechagin, Mikhail; Asatryan, Rubik

doi:10.1016/j.jaap.2016.07.004

Cited by 23 publications

(97 citation statements)

References 60 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Lignin pyrolysis chemistry is not that well understood in comparison to the other model components (cellulose and hemicellulose) due to its more complex structure. The bio‐oils from lignin consist of several aromatics, for example, benzene, toluene, biphenyl, and phenolics such as guaiacol, syringol, catechols, vanillins, and vinyl guaiacols (Bai et al, ; Custodis et al, ; Gai et al, ; Kawamoto & Saka, ; Khachatryan et al, ; Lou et al, ; Nowakowska et al, ; Scheer et al, ; Scheer et al, ). Lignin is known to decompose via competing pathways involving the bond cleavage of α‐O‐4, β‐O‐4, 5‐5 and 8‐5 bond linkages (Choi et al, ; Chu et al, ; Faravelli et al, ; Kawamoto & Saka, ; Kim et al, ).…”

Section: Mechanistic and Intrinsic Kinetic Studies Of Biomass Pyrolysismentioning

confidence: 99%

“…In EPR analysis, the pyrolysis radicals undergo a transition via energy absorption, based on which the nature of detected radical can be analyzed. In these studies the samples are first pyrolyzed in simple micro-tubular reactors made up of quartz in an electrically heated furnace (Asatryan et al, 2017;Khachatryan et al, 2016;Khachatryan, Asatryan, McFerrin, Adounkpe, & Dellinger, 2010;Kim et al, 2014Kim et al, , 2015Xu et al, 2016). The reactor effluent is immediately quenched in quartz tubes immersed in a bath of liquid nitrogen to prevent the conversion of intermediate radicals.…”

Section: Product Characterizationmentioning

confidence: 99%

“…Besides, these studies can also help in designing a suitable catalyst to improve the selectivity towards desired products (Butler et al, ; Li et al, ). Numerous studies have been performed over the years to decode the kinetic mechanisms of biomass fast pyrolysis (Agarwal, Dauenhauer, Huber, & Auerbach, ; Bai et al, ; Bai & Brown, ; Banyasz, Li, Lyons‐Hart, & Shafer, ; Bradbury, Sakai, & Shafizadeh, ; Branca, Di Blasi, Mango, & Hrablay, ; Broido & Nelson, ; Choi et al, ; Chu, Subrahmanyam, & Huber, ; Custodis, Hemberger, Ma, & van Bokhoven, ; Debiagi et al, ; Faravelli, Frassoldati, Migliavacca, & Ranzi, ; Gai et al, ; Huang, Liu, Tong, Li, & Wu, ; Huang, Liu, Wei, Huang, & Li, ; Kawamoto, Murayama, & Saka, ; Kawamoto & Saka, ; Khachatryan, Xu, Wu, Pechagin, & Asatryan, ; Kim, Bai, & Brown, ; Lou, Wu, & Lyu, ; Mayes & Broadbelt, ; Mayes, Nolte, Beckham, Shanks, & Broadbelt, ; Mettler, Mushrif, et al, 2012; Miller & Bellan, ; Norinaga, Shoji, Kudo, & Hayashi, ; Nowakowska, Herbinet, Dufour, & Glaude, ; Patwardhan, Dalluge, Shanks, & Brown, ; Patwardhan, Satrio, Brown, & Shanks, ; Piskorz, Majerski, Radlein, Vladars‐Usas, & Scott, ; Piskorz, Radlein, & Scott, ; Ranzi et al, , ; Ranzi, Debiagi, & Frassoldati, , ; Ronsse, Dalluge, Prins, & Brown, ; Scheer et al, ; Scheer, Mukarakate, Robichaud, Nimlos, & Ellison, ; Shafizadeh & Fu, ; Shen & Gu, ; Shen, Gu, & Bridgwater, ; Shen, Xiao, Gu, & Luo, ; Varhegyi, Jakab, & Antal, ; Vasiliou et al, ; Vinu & Broadbelt, ; Wang, Ru, Lin, & Luo, ; Werner, Pommer, & Broström, ; Zhang, Li, Yang, & Blasiak, ; Zhang, Nolte, & Shanks, ; Zhou, Li, Mabon, & Broadbelt, ; Zhou, Nolte, Mayes, Shanks, & Broadbelt,…”

Section: Introductionmentioning

confidence: 99%

“…Alternatively, model compounds of the three biomass constituents have been used to derive the details of intermediate species generated during their thermal decomposition. Pyrolysis of model compounds also provides insights on the influence of the substituent functional groups or bond linkages on the product distribution (Asatryan et al, ; Asmadi, Kawamoto, & Saka, ; Buckingham et al, ; Choi et al, ; Custodis et al, ; Jarvis et al, ; Kawamoto & Saka, ; Khachatryan et al, ; Lou et al, ; Nowakowska et al, ; Patwardhan et al, ; Robichaud, Nimlos, & Ellison, ; Scheer et al, ; Scheer et al, ; Scheer, Mukarakate, Robichaud, Ellison, & Nimlos, ; Vasiliou et al, ; Wang, McDonald, et al, ; Xu et al, ; Zhou, Nolte, et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…These studies provide information on the dominant types of reactions involved such as concerted, free-radical, or ion-driven mechanisms. In addition, mechanistic studies describe the type of reaction intermediates and competing pathways involved in the product formation (Asatryan, Bennadji, Bozzelli, Ruckenstein, & Khachatryan, 2017;Bahrle, Custodis, Jeschke, van Bokhoven, & Vogel, 2014;Custodis et al, 2014;Furutani, Dohara, Kudo, Hayashi, & Norinaga, 2018;Khachatryan et al, 2016;Kibet, Khachatryan, & Dellinger, 2012;Kim, Bai, Cady, Gable, & Brown, 2015;Koirala, Villano, Carstensen, & Dean, 2013;Qi, Zhang, Kudo, Norinaga, & Hayashi, 2017;Seshadri & Westmoreland, 2012;Shen, Jarboe, et al, 2015;Wornat, Ledesma, & Marsh, 2001;Xu, Khachatryan, Baev, & Asatryan, 2016). Advances in analytical techniques have made it possible to even detect intermediate radicals and important product species (Bahng et al, 2009;Kanaujia, Sharma, Agrawal, & Garg, 2013;Michailof, Kalogiannis, Sfetsas, Patiaka, & Lappas, 2016;Negahdar et al, 2016;Pouwels, Eijkel, & Boon, 1989;Sarrut et al, 2015;Traore, Kaal, & Martinez Cortizas, 2016).…”

mentioning

confidence: 99%

See 4 more Smart Citations

Measuring biomass fast pyrolysis kinetics: State of the art

SriBala

Carstensen

Marin

2018

WIREs Energy & Environment

View full text Add to dashboard Cite

Fast pyrolysis of lignocellulosic biomass is considered to be a promising thermochemical route for the production of drop‐in fuels and valuable chemicals. During the past decades, a comprehensive understanding of feedstock structure, fast pyrolysis kinetics, product distribution, and transport effects that govern the process has allowed to design better pyrolysis reactors and/or catalysts. A variety of lignocellulosic biomass feedstocks, like corn stover, pinewood, poplar, and model compounds like glucose, xylan, monolignols have been utilized to study the thermal decomposition at or close to fast pyrolysis conditions. Significant progress has been made in understanding the kinetics by developing unique setups such as drop‐tube, PHASR, and micropyrolyzer reactors in combination with the use of advanced analytical techniques such as comprehensive gas and liquid chromatography (GC, LC) with time‐of‐flight mass spectrometer (TOF‐MS). This has led to initial intrinsic kinetic models for biomass and its main components, namely cellulose, hemicellulose, and lignin, validated using experimental setups where the effects of heat and mass transfer on the performance of the process, expressed using Biot and pyrolysis numbers, are adequately negligible. Yet, not all aspects of fast pyrolysis kinetics of biomass components are equally well understood. The use of time‐resolved or multiplexed experimental techniques can further improve our understanding of reaction intermediates and their corresponding kinetic mechanisms. The novel experimental data combined with first principles based multiscale models can reshape biomass pyrolysis models and transform biomass fast pyrolysis to a more selective and energy efficient process. This article is categorized under: Energy and Climate > Climate and Environment Energy Research & Innovation > Science and Materials Bioenergy > Science and Materials

show abstract

Section: Mechanistic and Intrinsic Kinetic Studies Of Biomass Pyrolysismentioning

confidence: 99%

Section: Product Characterizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

See 3 more Smart Citations

Measuring biomass fast pyrolysis kinetics: State of the art

SriBala

Carstensen

Marin

2018

WIREs Energy & Environment

View full text Add to dashboard Cite

show abstract

Hydrothermal and Pyrolytic Conversion of Biomasses into Catalysts for Advanced Oxidation Treatments

Zheng

et al. 2020

Adv Funct Materials

View full text Add to dashboard Cite

Biomasses are very important natural products. Transferring biomass into catalysts for the advanced oxidation process (AOP) via heat treatment has attracted extensive attention. This review systematically introduces and summarizes two kinds of innovative biomass‐based catalysts according to the treating temperature. At low temperature (<300 °C), biomasses are converted into hydrothermal carbonation carbon (HTCC) with semiconductive properties for photocatalysis application. At high temperature (>300 °C), by contrast, the products lose their semiconductive nature and become a conductive carbon‐based conductor (biochar). They usually work as AOP catalysts by activating oxidant of O2, H2O2, and peroxysulfate for environmental treatment. This review summarizes and compares HTCC and biochar according to their formation process, structure, catalytic mechanism, and key points for the activity enhancement. The active units in HTCC are the sp2‐hybridized polyfuran unit while those in biochar are the persistent free radicals, nitrogen‐containing unit, or defects. HTCC converts water into OH radicals by using the photoexcited electron/hole pairs induced by solar illumination, while biochar activates oxidants via the active unit on its surface. More importantly, this review summarizes and demonstrates the key points to obtain high‐efficiency HTCC and biochar catalysts. Finally, conclusions are drawn and the future aspects for biomass‐based catalysis are given.

show abstract

Kinetic modeling of the pyrolysis chemistry of fossil and alternative feedstocks

Van Geem

2019

Computer Aided Chemical Engineering

View full text Add to dashboard Cite

Radicals and molecular products from the gas-phase pyrolysis of lignin model compounds. Cinnamyl alcohol

Cited by 23 publications

References 60 publications

Measuring biomass fast pyrolysis kinetics: State of the art

Measuring biomass fast pyrolysis kinetics: State of the art

Hydrothermal and Pyrolytic Conversion of Biomasses into Catalysts for Advanced Oxidation Treatments

Kinetic modeling of the pyrolysis chemistry of fossil and alternative feedstocks

Contact Info

Product

Resources

About