Home / Publications / Processing of lignocellulosic polymer wastes using microwave irradiation

Processing of lignocellulosic polymer wastes using microwave irradiation

Leonid Modestovich Kustov 1, 2
Leonid Modestovich Kustov
Aleksandr Leonidovich Kustov 1, 2
Aleksandr Leonidovich Kustov
Tapio Salmi 3
Tapio Salmi
10.1016/j.mencom.2022.01.001
Published 2022-01-03
Focus articleVolume 32, Issue 1, 1-8
20
Share
Cite this
GOST
 | 
Cite this
GOST Copy
Kustov L. M., Kustov A. L., Salmi T. Processing of lignocellulosic polymer wastes using microwave irradiation // Mendeleev Communications. 2022. Vol. 32. No. 1. pp. 1-8.
GOST all authors (up to 50) Copy
Kustov L. M., Kustov A. L., Salmi T. Processing of lignocellulosic polymer wastes using microwave irradiation // Mendeleev Communications. 2022. Vol. 32. No. 1. pp. 1-8.
RIS
 | 
Cite this
RIS Copy
TY - JOUR
DO - 10.1016/j.mencom.2022.01.001
UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2022.01.001
TI - Processing of lignocellulosic polymer wastes using microwave irradiation
T2 - Mendeleev Communications
AU - Kustov, Leonid Modestovich
AU - Kustov, Aleksandr Leonidovich
AU - Salmi, Tapio
PY - 2022
DA - 2022/01/03
PB - Mendeleev Communications
SP - 1-8
IS - 1
VL - 32
ER -
BibTex
 | 
Cite this
BibTex (up to 50 authors) Copy
@article{2022_Kustov,
author = {Leonid Modestovich Kustov and Aleksandr Leonidovich Kustov and Tapio Salmi},
title = {Processing of lignocellulosic polymer wastes using microwave irradiation},
journal = {Mendeleev Communications},
year = {2022},
volume = {32},
publisher = {Mendeleev Communications},
month = {Jan},
url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2022.01.001},
number = {1},
pages = {1--8},
doi = {10.1016/j.mencom.2022.01.001}
}
MLA
Cite this
MLA Copy
Kustov, Leonid Modestovich, et al. “Processing of lignocellulosic polymer wastes using microwave irradiation.” Mendeleev Communications, vol. 32, no. 1, Jan. 2022, pp. 1-8. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2022.01.001.
Views / Downloads
1 / 7

Keywords

catalysis
fuels
lignocellulosic wastes
low-temperature plasma
microwave irradiation
phenols

Abstract

Lignin and mixed lignocellulosic natural polymer wastes have been accumulated in landfills over the past hundred years. These wastes should be processed to produce added- value chemicals and materials. This mini-review presents a brief literature survey related to state-of-the-art methods developed recently by the world research community to solve the problem of rational conversion of lignocellulosic polymer wastes, including production of hydrogen, synthesis gas, phenols, and monomers. The focus is made on microwave and plasma technologies used for lignocellulosic wastes processing.

References

2.
Recent advances of greener pretreatment technologies of lignocellulose
Roy R., Rahman M.S., Raynie D.E.
Current Research in Green and Sustainable Chemistry, 2020
4.
Conversion of biomass lignin to high-value polyurethane: A review
Li H., Liang Y., Li P., He C.
Journal of Bioresources and Bioproducts, 2020
9.
10.1016/j.mencom.2022.01.001_b0045
Yao
Chem. Eng. J., 2021
10.
Thermal and catalytic conversion of waste polyolefines
Walendziewski J., Steininger M.
Catalysis Today, 2001
11.
Recycling of waste plastics into fuels. LDPE conversion in FCC
Passamonti F.J., Sedran U.
Applied Catalysis B: Environmental, 2012
12.
Catalytic pyrolysis of plastic waste: A review
Miandad R., Barakat M.A., Aburiazaiza A.S., Rehan M., Nizami A.S.
Process Safety and Environmental Protection, 2016
13.
Low temperature conversion of plastic waste into light hydrocarbons
Shah S.H., Khan Z.M., Raja I.A., Mahmood Q., Bhatti Z.A., Khan J., Farooq A., Rashid N., Wu D.
Journal of Hazardous Materials, 2010
14.
Thermal and thermo-catalytic conversion of waste polyolefins to fuel-like mixture of hydrocarbons
Stelmachowski M., Słowiński K.
Chemical and Process Engineering - Inzynieria Chemiczna i Procesowa, 2012
15.
Catalytic Pyrolysis of Plastic Waste: Moving Toward Pyrolysis Based Biorefineries
Miandad R., Rehan M., Barakat M.A., Aburiazaiza A.S., Khan H., Ismail I.M., Dhavamani J., Gardy J., Hassanpour A., Nizami A.
Frontiers in Energy Research, 2019
16.
Catalytic pyrolysis of HDPE in continuous mode over zeolite catalysts in a conical spouted bed reactor
Elordi G., Olazar M., Lopez G., Amutio M., Artetxe M., Aguado R., Bilbao J.
Journal of Analytical and Applied Pyrolysis, 2009
17.
Review Article: Recycling of Polystyrene
Maharana T., Negi Y.S., Mohanty B.
Polymer-Plastics Technology and Engineering, 2007
18.
Progress in the design of zeolite catalysts for biomass conversion into biofuels and bio-based chemicals
Serrano D.P., Melero J.A., Morales G., Iglesias J., Pizarro P.
Catalysis Reviews - Science and Engineering, 2017
19.
Co-pyrolysis of waste plastic and solid biomass for synergistic production of biofuels and chemicals-A review
Wang Z., Burra K.G., Lei T., Gupta A.K.
Progress in Energy and Combustion Science, 2021
20.
Catalytic co-pyrolysis of switchgrass and polyethylene over HZSM-5: Catalyst deactivation and coke formation
Mullen C.A., Dorado C., Boateng A.A.
Journal of Analytical and Applied Pyrolysis, 2018
21.
Catalytic Pyrolysis of Biomass and Polymer Wastes
Zhang L., Bao Z., Xia S., Lu Q., Walters K.
Catalysts, 2018
22.
10.1016/j.mencom.2022.01.001_b0110
Vasile
Cellul. Chem. Technol., 2006
24.
10.1016/j.mencom.2022.01.001_b0120
Rajendran
Mater. Today Commun., 2020
26.
Catalytic pyrolysis of polyethylene
Bagri R., Williams P.T.
Journal of Analytical and Applied Pyrolysis, 2002
27.
Characterization of Styrene Recovery from the Pyrolysis of Waste Expandable Polystyrene
Park J.J., Park K., Kim J., Maken S., Song H., Shin H., Park J., Choi M.
Energy & Fuels, 2003
28.
Microwave technology for energy-efficient processing of waste
Appleton T.J., Colder R.I., Kingman S.W., Lowndes I.S., Read A.G.
Applied Energy, 2005
29.
Microwave heating applications in environmental engineering—a review
Jones D.A., Lelyveld T.P., Mavrofidis S.D., Kingman S.W., Miles N.J.
Resources, Conservation and Recycling, 2002
30.
Plastics to fuel: a review
Kunwar B., Cheng H.N., Chandrashekaran S.R., Sharma B.K.
Renewable and Sustainable Energy Reviews, 2016
32.
Microwave pyrolysis of polymeric materials: Waste tires treatment and characterization of the value-added products
Undri A., Meini S., Rosi L., Frediani M., Frediani P.
Journal of Analytical and Applied Pyrolysis, 2013
33.
A review on the microwave-assisted pyrolysis technique
Motasemi F., Afzal M.T.
Renewable and Sustainable Energy Reviews, 2013
34.
One man's trash...
Cyranoski D.
Nature, 2006
36.
Fast co-pyrolysis of low density polyethylene and biomass residue for oil production
Yang J., Rizkiana J., Widayatno W.B., Karnjanakom S., Kaewpanha M., Hao X., Abudula A., Guan G.
Energy Conversion and Management, 2016
37.
Microwave co-pyrolysis of waste polyolefins and waste cooking oil: Influence of N2 atmosphere versus vacuum environment
Wan Mahari W.A., Chong C.T., Lam W.H., Anuar T.N., Ma N.L., Ibrahim M.D., Lam S.S.
Energy Conversion and Management, 2018
38.
Resource recovery from synthetic polymers via microwave pyrolysis using different susceptors
Suriapparao D.V., Vinu R.
Journal of Analytical and Applied Pyrolysis, 2015
40.
Evaluation of hardwood and softwood fractionation using autohydrolysis and ionic liquid microwave pretreatment
Rigual V., Santos T.M., Domínguez J.C., Alonso M.V., Oliet M., Rodriguez F.
Biomass and Bioenergy, 2018
41.
Unravelling the mechanisms of microwave pyrolysis of biomass
Robinson J., Binner E., Vallejo D.B., Perez N.D., Al Mughairi K., Ryan J., Shepherd B., Adam M., Budarin V., Fan J., Gronnow M., Peneranda-Foix F.
Chemical Engineering Journal, 2022
42.
Microwave assisted rapid conversion of carbohydrates into 5-hydroxymethylfurfural catalyzed by mesoporous TiO2 nanoparticles
Dutta S., De S., Patra A.K., Sasidharan M., Bhaumik A., Saha B.
Applied Catalysis A: General, 2011
44.
Microwave-assisted hydrolysis of polysaccharides over polyoxometalate clusters
Tsubaki S., Oono K., Ueda T., Onda A., Yanagisawa K., Mitani T., Azuma J.
Bioresource Technology, 2013
45.
Chemo-selective high yield microwave assisted reaction turns cellulose to green chemicals
Hassanzadeh S., Aminlashgari N., Hakkarainen M.
Carbohydrate Polymers, 2014
47.
Microwave pyrolysis of cellulose at low temperature
Al Shra’ah A., Helleur R.
Journal of Analytical and Applied Pyrolysis, 2014
50.
Microwave-assisted conversion of novel biomass materials into levulinic acid
Lappalainen K., Vogeler N., Kärkkäinen J., Dong Y., Niemelä M., Rusanen A., Ruotsalainen A.L., Wäli P., Markkola A., Lassi U.
Biomass Conversion and Biorefinery, 2018
51.
The Path Ahead for Ionic Liquids
Joglekar H. ., Rahman I., Kulkarni B. .
Chemical Engineering and Technology, 2007
52.
Applications of ionic liquids in the chemical industry
Plechkova N.V., Seddon K.R.
Chemical Society Reviews, 2008
57.
Microwave-assisted conversion of microcrystalline cellulose to 5-hydroxymethylfurfural catalyzed by ionic liquids.
Qu Y., Wei Q., Li H., Oleskowicz-Popiel P., Huang C., Xu J.
Bioresource Technology, 2014
58.
10.1016/j.mencom.2022.01.001_b0290
Liu
BioResources, 2017
60.
Rapid microwave-assisted biomass delignification and lignin depolymerization in deep eutectic solvents
Muley P.D., Mobley J.K., Tong X., Novak B., Stevens J., Moldovan D., Shi J., Boldor D.
Energy Conversion and Management, 2019
61.
Pretreatment of waste biomass in deep eutectic solvents: Conductive heating versus microwave heating
Kumar N., Muley P.D., Boldor D., Coty G.G., Lynam J.G.
Industrial Crops and Products, 2019
63.
Microwave assisted decomposition of cellulose: A new thermochemical route for biomass exploitation
Budarin V.L., Clark J.H., Lanigan B.A., Shuttleworth P., Macquarrie D.J.
Bioresource Technology, 2010
66.
Dilute Acid Hydrolysis of Cellulose and Cellulosic Bio-Waste Using a Microwave Reactor System
Orozco A., Ahmad M., Rooney D., Walker G.
Process Safety and Environmental Protection, 2007
68.
Microwave pretreatment of lignocellulosic material in cholinium ionic liquid for efficient enzymatic saccharification
Ninomiya K., Yamauchi T., Ogino C., Shimizu N., Takahashi K.
Biochemical Engineering Journal, 2014
69.
Detailed compositional analysis and structural investigation of a bio-oil from microwave pyrolysis of kraft lignin
Farag S., Fu D., Jessop P.G., Chaouki J.
Journal of Analytical and Applied Pyrolysis, 2014
70.
Microwave-assisted depolymerization of various types of waste lignins over two-dimensional CuO/BCN catalysts
Cao Y., Chen S.S., Tsang D.C., Clark J.H., Budarin V.L., Hu C., Wu K.C., Zhang S.
Green Chemistry, 2020
73.
Microwave-assisted depolymerisation of organosolv lignin via mild hydrogen-free hydrogenolysis: Catalyst screening
Toledano A., Serrano L., Pineda A., Romero A.A., Luque R., Labidi J.
Applied Catalysis B: Environmental, 2014
74.
Effect of Various Microwave Absorbents on the Microwave-Assisted Lignin Depolymerization Process
Wang W., Ma Z., Zhao X., Liu S., Cai L., Shi S.Q., Ni Y.
ACS Sustainable Chemistry and Engineering, 2020
75.
Bio-based phenols and fuel production from catalytic microwave pyrolysis of lignin by activated carbons.
Bu Q., Lei H., Wang L., Wei Y., Zhu L., Zhang X., Liu Y., Yadavalli G., Tang J.
Bioresource Technology, 2014
76.
Production of phenols and biofuels by catalytic microwave pyrolysis of lignocellulosic biomass
Bu Q., Lei H., Ren S., Wang L., Zhang Q., Tang J., Ruan R.
Bioresource Technology, 2012
77.
10.1016/j.mencom.2022.01.001_b0385
Wang
J. Energy Inst., 1997
78.
Microwave-assisted co-pyrolysis of lignin and waste oil catalyzed by hierarchical ZSM-5/MCM-41 catalyst to produce aromatic hydrocarbons
Zou R., Wang Y., Jiang L., Yu Z., Zhao Y., Wu Q., Dai L., Ke L., Liu Y., Ruan R.
Bioresource Technology, 2019
79.
10.1016/j.mencom.2022.01.001_b0395
Zhu
Bioresour. Technol., 1964
81.
A review on microwave assisted pyrolysis of coal and biomass for fuel production
Mushtaq F., Mat R., Ani F.N.
Renewable and Sustainable Energy Reviews, 2014
83.
Effect of biomass type, heating rate, and sample size on microwave-enhanced fast pyrolysis product yields and qualities
Klinger J.L., Westover T.L., Emerson R.M., Williams C.L., Hernandez S., Monson G.D., Ryan J.C.
Applied Energy, 2018
84.
Production of bio-oil from agricultural waste by using a continuous fast microwave pyrolysis system
Wang Y., Zeng Z., Tian X., Dai L., Jiang L., Zhang S., Wu Q., Wen P., Fu G., Liu Y., Ruan R.
Bioresource Technology, 2018
85.
Paving the Way for Lignin Valorisation: Recent Advances in Bioengineering, Biorefining and Catalysis
Rinaldi R., Jastrzebski R., Clough M.T., Ralph J., Kennema M., Bruijnincx P.C., Weckhuysen B.M.
Angewandte Chemie - International Edition, 2016
86.
Microwave-enhanced CO2 gasification of oil palm shell char
Lahijani P., Zainal Z.A., Mohamed A.R., Mohammadi M.
Bioresource Technology, 2014
88.
Fast microwave-assisted catalytic gasification of biomass for syngas production and tar removal
Xie Q., Borges F.C., Cheng Y., Wan Y., Li Y., Lin X., Liu Y., Hussain F., Chen P., Ruan R.
Bioresource Technology, 2014
89.
Influence of the microwave absorbent and moisture content on the microwave pyrolysis of an organic municipal solid waste
Beneroso D., Bermúdez J.M., Arenillas A., Menéndez J.A.
Journal of Analytical and Applied Pyrolysis, 2014
93.
Caroko N., Saptoadi H., Rohmat T.A.
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 2020
94.
Production of value-added liquid fuel via microwave co-pyrolysis of used frying oil and plastic waste
Wan Mahari W.A., Chong C.T., Cheng C.K., Lee C.L., Hendrata K., Yuh Yek P.N., Ma N.L., Lam S.S.
Energy, 2018
95.
Catalytic and atmospheric effects on microwave pyrolysis of corn stover
Huang Y., Kuan W., Chang C., Tzou Y.
Bioresource Technology, 2013
96.
10.1016/j.mencom.2022.01.001_b0480
Koberg
New and Future Developments in Catalysis, ed, 2013
97.
Effect of temperature and additives on the yields of products and microwave pyrolysis behaviors of wheat straw
Zhao X., Wang M., Liu H., Zhao C., Ma C., Song Z.
Journal of Analytical and Applied Pyrolysis, 2013
98.
Microwave pyrolysis of wheat straw: Product distribution and generation mechanism
Zhao X., Wang W., Liu H., Ma C., Song Z.
Bioresource Technology, 2014
99.
Catalytic pyrolysis of sugarcane bagasse by using microwave heating
Kuan W., Huang Y., Chang C., Lo S.
Bioresource Technology, 2013
100.
Cellulose esters from waste cotton fabric via conventional and microwave heating
Ratanakamnuan U., Atong D., Aht-Ong D.
Carbohydrate Polymers, 2012
101.
10.1016/j.mencom.2022.01.001_b0505
Microwaves in Catalysis
Methodology and Applications, eds, 2015
102.
Influence of catalyst types on the microwave-induced pyrolysis of sewage sludge
Yu Y., Yu J., Sun B., Yan Z.
Journal of Analytical and Applied Pyrolysis, 2014
103.
Liquefaction process for a hydrothermally treated waste mixture containing plastics
Sugano M., Komatsu A., Yamamoto M., Kumagai M., Shimizu T., Hirano K., Mashimo K.
Journal of Material Cycles and Waste Management, 2009
104.
10.1016/j.mencom.2022.01.001_b0520
Cansell
Revue de l’Institut Francais du Petrole, 1998
105.
Microwave-mediated non-catalytic transesterification of algal biomass under supercritical ethanol conditions
Patil P.D., Reddy H., Muppaneni T., Ponnusamy S., Cooke P., Schuab T., Deng S.
Journal of Supercritical Fluids, 2013
106.
Comparison of direct transesterification of algal biomass under supercritical methanol and microwave irradiation conditions
Patil P.D., Gude V.G., Mannarswamy A., Cooke P., Nirmalakhandan N., Lammers P., Deng S.
Fuel, 2012
108.
Unconventional Pretreatment of Lignocellulose with Low-Temperature Plasma
Vanneste J., Ennaert T., Vanhulsel A., Sels B.
ChemSusChem, 2016
110.
Kraft Lignin Conversion into Energy Carriers under the Action of Electromagnetic Radiation
Zharova P., Arapova O.V., Konstantinov G.I., Chistyakov A.V., Tsodikov M.V.
Journal of Chemistry, 2019
111.
Production of Motor Fuel from Lignocellulose in a Three-Stage Process (Review and Experimental Article)
Netrusov A.I., Teplyakov V.V., Tsodikov M.V., Chistyakov A.V., Zharova P.A., Shalygin M.G.
Petroleum Chemistry, 2019
112.
Fe-containing nanoparticles used as effective catalysts of lignin reforming to syngas and hydrogen assisted by microwave irradiation
Tsodikov M.V., Ellert O.G., Nikolaev S.A., Arapova O.V., Bukhtenko O.V., Maksimov Y.V., Kirdyankin D.I., Vasil’kov A.Y.
Journal of Nanoparticle Research, 2018
113.
10.1016/j.mencom.2022.01.001_b0565
Tsodikov
Chem. Eng. Trans., 2018
114.
10.1016/j.mencom.2022.01.001_b0570
Kobayashi
J. Jpn. Inst. Energy, 2005
115.
The role of nanosized nickel particles in microwave-assisted dry reforming of lignin
Tsodikov M.V., Ellert O.G., Nikolaev S.A., Arapova O.V., Konstantinov G.I., Bukhtenko O.V., Vasil’kov A.Y.
Chemical Engineering Journal, 2017
116.
10.1016/j.mencom.2022.01.001_b0580
Zhou
Bioresour. Technol., 2020
117.
Plasma-enabled liquefaction of lignocellulosic biomass: Balancing feedstock content for maximum energy yield
Mei D., Liu S., Wang S., Zhou R., Zhou R., Fang Z., Zhang X., Cullen P.J., Ostrikov K.(.
Renewable Energy, 2020
118.
The universality of lignocellulosic biomass liquefaction by plasma electrolysis under acidic conditions
Xi D., Jiang C., Zhou R., Fang Z., Zhang X., Liu Y., Luan B., Feng Z., Chen G., Chen Z., Liu Q., Yang S.
Bioresource Technology, 2018
119.
Non-thermal gas-phase pulsed corona discharge for lignin modification
Sokolov A., Lagerquist L., Eklund P., Louhi-Kultanen M.
Chemical Engineering and Processing: Process Intensification, 2018
120.
Review of microwave-assisted lignin conversion for renewable fuels and chemicals
Yunpu W., Leilei D., Liangliang F., Shaoqi S., Yuhuan L., Roger R.
Journal of Analytical and Applied Pyrolysis, 2016
121.
A review of catalytic microwave pyrolysis of lignocellulosic biomass for value-added fuel and chemicals
Morgan H.M., Bu Q., Liang J., Liu Y., Mao H., Shi A., Lei H., Ruan R.
Bioresource Technology, 2017
122.
Opportunities for utilization of non-conventional energy sources for biomass pretreatment
Singh R., Krishna B.B., Kumar J., Bhaskar T.
Bioresource Technology, 2016
123.
Kustov L.M., Tarasov A.L., Kustov A.L.
Mendeleev Communications, 2020
124.
Kustov L.M., Tarasov A.L., Nissenbaum V.D., Kustov A.L.
Mendeleev Communications, 2021