Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/wiley/experimental-processing-of-seaweeds-for-biofuels-Tg6Fkh0vHF
References (117)
-
R. Rajkumar, Z. Yaakob, M. Takriff (2013)
Potential of the micro and macro algae for biofuel production: a brief review.Bioresources, 9
-
V. Ashokkumar, M. Salim, Z. Salam, P. Sivakumar, C. Chong, S. Elumalai, V. Suresh, F. Ani (2017)
Production of liquid biofuels (biodiesel and bioethanol) from brown marine macroalgae Padina tetrastromaticaEnergy Conversion and Management, 135
-
J. Lee, Pan Li, Jieun Lee, H. Ryu, K. Oh (2013)
Ethanol production from Saccharina japonica using an optimized extremely low acid pretreatment followed by simultaneous saccharification and fermentation.Bioresource technology, 127
-
Annette Bruhn, J. Dahl, H. Nielsen, L. Nikolaisen, M. Rasmussen, S. Markager, B. Olesen, C. Arias, P. Jensen (2011)
Bioenergy potential of Ulva lactuca: biomass yield, methane production and combustion.Bioresource technology, 102 3
-
H. Wal, B.L.H.M. Sperber, Bwee Houweling-Tan, R. Bakker, W. Brandenburg, A. López-Contreras (2013)
Production of acetone, butanol, and ethanol from biomass of the green seaweed Ulva lactuca.Bioresource technology, 128
-
G. Roesijadi, S. Jones, L. Snowden‐Swan, Yunhua Zhu (2010)
Macroalgae as a Biomass Feedstock: A Preliminary Analysis -
Amita Jacob, A. Xia, Daryl Gunning, G. Burnell, J. Murphy (2016)
Seaweed Biofuel Derived from Integrated Multi-trophic AquacultureInternational journal of environmental science and development, 7
-
J. Wilkinson, K. Bolsen, C. Lin (2015)
History of Silage -
S. Siddiqua, A. Mamun, Sheikh Babar (2015)
Production of biodiesel from coastal macroalgae (Chara vulgaris) and optimization of process parameters using Box-Behnken designSpringerPlus, 4
-
Y. Barbot, Hashem Al-Ghaili, R. Benz (2016)
A Review on the Valorization of Macroalgal Wastes for Biomethane ProductionMarine Drugs, 14
-
Rui Jiang, K. Ingle, A. Golberg (2016)
Macroalgae (seaweed) for liquid transportation biofuel production: what is next?Algal Research-Biomass Biofuels and Bioproducts, 14
-
F. Murphy, Ger Devlin, Rory Deverell, K. McDonnell (2013)
Biofuel Production in Ireland—An Approach to 2020 Targets with a Focus on Algal BiomassEnergies, 6
-
G. Brem, E. Bramer, T. Meer (2002)
Thermal conversion of biomass -
A. Demirbaş, M. Demirbas (2010)
Algae Energy: Algae as a New Source of Biodiesel -
G. Marquez, H. Takeuchi, T. Hasegawa (2015)
Biogas Production of Biologically and Chemically-pretreated Seaweed, Ulva spp., under Different Conditions: Freshwater and ThalassicJournal of The Japan Institute of Energy, 94
-
J. Hal, W. Huijgen, A. López-Contreras (2014)
Opportunities and challenges for seaweed in the biobased economy.Trends in biotechnology, 32 5
-
(2012)
Additionally, algae can be cultivated in land areas that are unsuitable for agricultural purposes -
JS Rowbotham, P. Dyer, H. Greenwell, M. Theodorou (2012)
Thermochemical processing of macroalgae: a late bloomer in the development of third-generation biofuels?Biofuels, 3
-
A. Smith, A. Ross (2016)
Production of bio-coal, bio-methane and fertilizer from seaweed via hydrothermal carbonisationAlgal Research-Biomass Biofuels and Bioproducts, 16
-
Kyung Jung, Seong-Rin Lim, Yoori Kim, J. Park (2013)
Potentials of macroalgae as feedstocks for biorefinery.Bioresource technology, 135
-
D. Brockmann, C. Pradinaud, J. Champenois, Maud Benoît, A. Hélias (2015)
Environmental assessment of bioethanol from onshore grown green seaweedBiofuels, 9
-
G. Sivakumar, D. Vail, Jianfeng Xu, D. Burner, J. Lay, X. Ge, P. Weathers (2010)
Bioethanol and biodiesel: Alternative liquid fuels for future generationsEngineering in Life Sciences, 10
-
Svein Horn, I. Aasen, K. Østgaard (2000)
Ethanol production from seaweed extractJournal of Industrial Microbiology and Biotechnology, 25
-
J. Costa, P. Gonçalves, A. Nobre, M. Alves (2012)
Biomethanation potential of macroalgae Ulva spp. and Gracilaria spp. and in co-digestion with waste activated sludge.Bioresource technology, 114
-
Melinda Lo, L. Abrahamson (1996)
Principal component analysis to evaluate the relative performance of nine year old hybrid poplar clonesBiomass & Bioenergy, 10
-
A. Khan, Noureen Fatima, M. Hussain, Kousar Yasmeen (2016)
Biodiesel production from green seaweed Ulva fasciata catalyzed by novel waste catalysts from Pakistan Steel IndustryChinese Journal of Chemical Engineering, 24
-
B. Yoza, Evan Masutani (2013)
The analysis of macroalgae biomass found around Hawaii for bioethanol productionEnvironmental Technology, 34
-
Wenchao Yang, Xianguo Li, Shishi Liu, Lijuan Feng (2014)
Direct hydrothermal liquefaction of undried macroalgae Enteromorpha prolifera using acid catalysts.Energy Conversion and Management, 87
-
Björn Gosch, M. Magnusson, N. Paul, R. Nys (2012)
Total lipid and fatty acid composition of seaweeds for the selection of species for oil‐based biofuel and bioproductsGCB Bioenergy, 4
-
(2008)
Algae (2nd ed.) -
M. Schumacher, J. Yanık, A. Sinağ, A. Kruse (2011)
Hydrothermal conversion of seaweeds in a batch autoclaveJournal of Supercritical Fluids, 58
-
Mitsunori Yanagisawa, S. Kawai, K. Murata (2013)
Strategies for the production of high concentrations of bioethanol from seaweedsBioengineered, 4
-
Anam Saqib, Muhammad Tabbssum, U. Rashid, M. Ibrahim, M. Mehmood (2013)
MARINE MACRO ALGAE ULVA : A POTENTIAL FEED-STOCK FOR BIO- ETHANOL AND BIOGAS PRODUCTION -
S. Mussatto, I. Roberto (2004)
Alternatives for detoxification of diluted-acid lignocellulosic hydrolyzates for use in fermentative processes: a review.Bioresource technology, 93 1
-
(2015)
Production of biofuels from marine macroalgae Melanothamnus afaqhusainii and Ulva fasciata -
G. Marquez, Taro Noboribayashi, Tatsuo Takahashi, Y. Fujii, H. Takeuchi, T. Hasegawa (2016)
Performance of semi-continuous fixed-bed digester for thalassic biogas production of the brown seaweed, Ecklonia spp.Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 38
-
S. Kawai, K. Murata (2016)
Biofuel Production Based on Carbohydrates from Both Brown and Red Macroalgae: Recent Developments in Key BiotechnologiesInternational Journal of Molecular Sciences, 17
-
Forough Naghdi, Lina González, W. Chan, P. Schenk (2016)
Progress on lipid extraction from wet algal biomass for biodiesel productionMicrobial Biotechnology, 9
-
M. Aresta, A. Dibenedetto, M. Carone, T. Colonna, C. Fragale (2005)
Production of biodiesel from macroalgae by supercritical CO2 extraction and thermochemical liquefactionEnvironmental Chemistry Letters, 3
-
Xin Deng, Zhen Fang, Yun-hu Liu (2010)
Ultrasonic transesterification of Jatropha curcas L. oil to biodiesel by a two-step processEnergy Conversion and Management, 51
-
S. Tedesco, J. Stokes (2016)
Valorisation to biogas of macroalgal waste streams: a circular approach to bioproducts and bioenergy in IrelandChemicke Zvesti, 71
-
T. Suganya, N. Gandhi, S. Renganathan (2013)
Production of algal biodiesel from marine macroalgae Enteromorpha compressa by two step process: optimization and kinetic study.Bioresource technology, 128
-
I. Michalak, R. Wilk, K. Chojnacka (2017)
Bioconversion of Baltic Seaweeds into Organic CompostWaste and Biomass Valorization, 8
-
Muhammad Tabassum, D. Wall, J. Murphy (2016)
Biogas production generated through continuous digestion of natural and cultivated seaweeds with dairy slurry.Bioresource technology, 219
-
C. Vanegas, J. Bartlett (2013)
Green energy from marine algae: biogas production and composition from the anaerobic digestion of Irish seaweed speciesEnvironmental Technology, 34
-
I. Michalak, K. Chojnacka (2015)
Algae as production systems of bioactive compoundsEngineering in Life Sciences, 15
-
Y. Chisti (2007)
Biodiesel from microalgae.Biotechnology advances, 25 3
-
A. Peterson, F. Vogel, R. Lachance, M. Fröling, M. Antal, J. Tester (2008)
Thermochemical biofuel production in hydrothermal media: A review of sub- and supercritical water technologiesEnergy and Environmental Science, 1
-
Rawel Singh, Bhavya Balagurumurthy, T. Bhaskar (2015)
Hydrothermal liquefaction of macro algae: Effect of feedstock compositionFuel, 146
-
Leor Korzen, I. Pulidindi, Á. Israel, A. Abelson, A. Gedanken (2015)
Single step production of bioethanol from the seaweed Ulva rigida using sonicationRSC Advances, 5
-
E. Allen, J. Browne, J. Murphy (2013)
Evaluation of the biomethane yield from anaerobic co-digestion of nitrogenous substratesEnvironmental Technology, 34
-
L. Brennan, P. Owende (2010)
Biofuels from microalgae—A review of technologies for production, processing, and extractions of biofuels and co-productsRenewable & Sustainable Energy Reviews, 14
-
Y. Khambhaty, D. Upadhyay, Y. Kriplani, Nidhi Joshi, K. Mody, M. Gandhi (2013)
Bioethanol from Macroalgal Biomass: Utilization of Marine Yeast for Production of the SameBioEnergy Research, 6
-
N. Skoglund, K. Werner, G. Nylund, H. Pavia, E. Albers, M. Broström (2017)
Combustion of seaweed : A fuel design strategyFuel Processing Technology, 165
-
M. Borines, R. Leon, J. Cuello (2013)
Bioethanol production from the macroalgae Sargassum spp.Bioresource technology, 138
-
Aaron Philippsen, P. Wild, A. Rowe (2014)
Energy input, carbon intensity and cost for ethanol produced from farmed seaweedRenewable & Sustainable Energy Reviews, 38
-
D. Suh, J. Choi, H. Woo (2014)
Pyrolysis of Seaweeds for Bio-oil and Bio-char ProductionChemical engineering transactions, 37
-
G. Najafi, B. Ghobadian, T. Yusaf (2011)
Algae as a sustainable energy source for biofuel production in Iran: A case studyRenewable & Sustainable Energy Reviews, 15
-
K. Bech (2011)
Energy Production from Marine Biomass ( Ulva lactuca ) PSO Project No -
Nadja Schultz-Jensen, A. Thygesen, F. Leipold, S. Thomsen, Christian Roslander, H. Lilholt, A. Bjerre (2013)
Pretreatment of the macroalgae Chaetomorpha linum for the production of bioethanol--comparison of five pretreatment technologies.Bioresource technology, 140
-
(2014)
They can also be farmed on a large scale without the use of fresh water, arable -
(2018)
How to cite this article: Michalak I. Experimental processing of seaweeds for biofuels -
J. Milledge, P. Harvey (2016)
Potential process ‘hurdles’ in the use of macroalgae as feedstock for biofuel production in the British IslesJournal of Chemical Technology and Biotechnology, 91
-
Q. Bach, M. Sillero, K. Tran, J. Skjermo (2014)
Fast hydrothermal liquefaction of a Norwegian macro-alga: Screening testsAlgal Research-Biomass Biofuels and Bioproducts, 6
-
Y. Bae, C. Ryu, Jong-Ki Jeon, Junhong Park, D. Suh, Y. Suh, D. Chang, Young‐Kwon Park (2011)
The characteristics of bio-oil produced from the pyrolysis of three marine macroalgae.Bioresource technology, 102 3
-
A. Ross, J. Jones, M. Kubacki, T. Bridgeman (2008)
Classification of macroalgae as fuel and its thermochemical behaviour.Bioresource technology, 99 14
-
E. Allen, J. Browne, S. Hynes, J. Murphy (2013)
The potential of algae blooms to produce renewable gaseous fuel.Waste management, 33 11
-
Shuvashish Behera, Richa Singh, R. Arora, N. Sharma, M. Shukla, Sachin Kumar (2015)
Scope of Algae as Third Generation BiofuelsFrontiers in Bioengineering and Biotechnology, 2
-
A. Afify, E. Shalaby, S. Shanab (2010)
Enhancement of biodiesel production from different species of algaeGrasas Y Aceites, 61
-
(2015)
Synthesis of biodiesel from the oily content of marine green alga Ulva fasciata -
J. Frigon, Serge Guiot (2010)
Biomethane production from starch and lignocellulosic crops: a comparative reviewBiofuels, 4
-
G. Rajauria, L. Cornish, Francesco Ometto, F. Msuya, R. Villa (2015)
Identification and selection of algae for food, feed, and fuel applications -
Andrew Ross, K. Anastasakis, M. Kubacki, Jenny Jones (2009)
Investigation of the pyrolysis behaviour of brown algae before and after pre-treatment using PY-GC/MS and TGAJournal of Analytical and Applied Pyrolysis, 85
-
(2015)
Transesterification can be performed under acidic (for a higher -
V. Nkemka, Jorge Arenales-Rivera, M. Murto (2014)
Two-Stage Dry Anaerobic Digestion of Beach Cast Seaweed and Its Codigestion with Cow Manure, 2014
-
(2008)
Dubois-Calero N -
Siti Mutripah, M. Meinita, Ji‐Young Kang, Gwi-Taek Jeong, A. Susanto, R. Prabowo, Yong-Ki Hong (2013)
Bioethanol production from the hydrolysate of Palmaria palmata using sulfuric acid and fermentation with brewer’s yeastJournal of Applied Phycology, 26
-
Mohsen Ghadiryanfar, K. Rosentrater, A. Keyhani, M. Omid (2016)
A review of macroalgae production, with potential applications in biofuels and bioenergyRenewable & Sustainable Energy Reviews, 54
-
Oluwatosin Obata, J. Akunna, H. Bockhorn, G. Walker (2016)
Ethanol production from brown seaweed using non-conventional yeastsBioethanol, 2
-
G. Marquez, Wilfred Santiañez, G. Trono, M. Montaño, H. Araki, H. Takeuchi, T. Hasegawa (2014)
Seaweed biomass of the Philippines: Sustainable feedstock for biogas productionRenewable & Sustainable Energy Reviews, 38
-
K. Anastasakis, A. Ross (2011)
Hydrothermal liquefaction of the brown macro-alga Laminaria saccharina: effect of reaction conditions on product distribution and composition.Bioresource technology, 102 7
-
D. Shallcross, T. Harrison, A. Rivett, J. Tuah (2012)
Handbook of Climate Change MitigationSpringer US
-
(2009)
Seaweed biofuels: Production of biogas and bioethanol from brown macroalgae. Saarbrücken, Germany: VDM -
Yanqun Li, M. Horsman, Nan Wu, C. Lan, Nathalie Dubois-Calero (2008)
Biofuels from MicroalgaeBiotechnology Progress, 24
-
Huihui Chen, D. Zhou, G. Luo, Shicheng Zhang, Jianmin Chen (2015)
Macroalgae for biofuels production: progress and perspectives.Renewable & Sustainable Energy Reviews, 47
-
(2017)
Studies on eco-friendly production of biodiesel from marine seaweed -
J. Milledge, Benjamin Smith, Philip Dyer, P. Harvey (2014)
Macroalgae-Derived Biofuel: A Review of Methods of Energy Extraction from Seaweed BiomassEnergies, 7
-
Hiroyuki Takeda, F. Yoneyama, S. Kawai, W. Hashimoto, K. Murata (2011)
Bioethanol production from marine biomass alginate by metabolically engineered bacteriaEnergy and Environmental Science, 4
-
Linhua Song, Ming-Ming Hu, Dong Liu, Daoxiang Zhang, Cuiyu Jiang (2014)
Thermal cracking of Enteromorpha prolifera with solvents to bio-oilEnergy Conversion and Management, 77
-
M. Hannon, J. Gimpel, Miller Tran, Beth Rasala, S. Mayfield (2010)
Biofuels from algae: challenges and potentialBiofuels, 1
-
(2009)
A review of the potential of marine algae as a source of biofuel in Ireland ( Report published by the Sustainable Energy Authority of Ireland ) . SEI , Sustainable Energy Ireland , Dublin -
G. Jard, H. Marfaing, H. Carrère, J. Delgenès, J. Steyer, Claire Dumas (2013)
French Brittany macroalgae screening: composition and methane potential for potential alternative sources of energy and products.Bioresource technology, 144
-
M. Enquist-Newman, A. Faust, Daniel Bravo, C. Santos, Ryan Raisner, A. Hanel, Preethi Sarvabhowman, Chieu Le, Drew Regitsky, S. Cooper, Lars Peereboom, A. Clark, Yessica Martinez, J. Goldsmith, Min-Young Cho, Paul Donohoue, Li-Jun Luo, Brigit Lamberson, P. Tamrakar, Edward Kim, J. Villari, A. Gill, Shital Tripathi, P. Karamchedu, C. Paredes, V. Rajgarhia, H. Kotlar, R. Bailey, Dennis Miller, Nicholas Ohler, C. Swimmer, Y. Yoshikuni (2013)
Efficient ethanol production from brown macroalgae sugars by a synthetic yeast platformNature, 505
-
S. Bastianoni, F. Coppola, E. Tiezzi, A. Colacevich, F. Borghini, S. Focardi (2008)
Biofuel potential production from the Orbetello lagoon macroalgae : A comparison with sunflower feedstockBiomass & Bioenergy, 32
-
P. Peu, J. Sassi, R. Girault, S. Picard, Patricia Saint-Cast, F. Béline, P. Dabert (2011)
Sulphur fate and anaerobic biodegradation potential during co-digestion of seaweed biomass (Ulva sp.) with pig slurry.Bioresource technology, 102 23
-
D. Zhou, Liangbo Zhang, Shicheng Zhang, Hongbo Fu, Jianmin Chen (2010)
Hydrothermal Liquefaction of Macroalgae Enteromorpha prolifera to Bio-oilEnergy & Fuels, 24
-
(2016)
Algal biomass can contribute to the reduction of greenhouse gas emissions and climate change -
V. Vivekanand, V. Eijsink, S. Horn (2012)
Biogas production from the brown seaweed Saccharina latissima: thermal pretreatment and codigestion with wheat strawJournal of Applied Phycology, 24
-
Balakrishna Maddi, S. Viamajala, S. Varanasi (2011)
Comparative study of pyrolysis of algal biomass from natural lake blooms with lignocellulosic biomass.Bioresource technology, 102 23
-
K. Anastasakis, A. Ross (2015)
Hydrothermal liquefaction of four brown macro-algae commonly found on the UK coasts: An energetic analysis of the process and comparison with bio-chemical conversion methodsFuel, 139
-
I. Michalak, K. Chojnacka (2014)
Algal extracts: Technology and advancesEngineering in Life Sciences, 14
-
M. Jerry, Drosg Bernhard, Allen Eoin, Jerney Jacqueline, Xianglong Ao, Herrmann Christiane (2015)
A perspective on algal biogas -
P. Morand, X. Briand, R. Charlier (2006)
Anaerobic Digestion of Ulva sp. 3. Liquefaction Juices Extraction by Pressing and a Technico-Economic BudgetJournal of Applied Phycology, 18
-
(2016)
2016) provided a review of algal extraction techniques and pretreatment methods and demonstrated that among -
P. Bikker, M. Krimpen, P. Wikselaar, Bwee Houweling-Tan, N. Scaccia, Jaap Hal, W. Huijgen, J. Cone, A. López-Contreras (2016)
Biorefinery of the green seaweed Ulva lactuca to produce animal feed, chemicals and biofuelsJournal of Applied Phycology, 28
-
J. Langlois, J. Sassi, G. Jard, J. Steyer, J. Delgenès, A. Hélias (2012)
Life cycle assessment of biomethane from offshore‐cultivated seaweedBiofuels, 6
-
V. Nkemka, M. Murto (2010)
Evaluation of biogas production from seaweed in batch tests and in UASB reactors combined with the removal of heavy metals.Journal of environmental management, 91 7
-
Michele Seghetta, Daina Romeo, Martina D'Este, M. Alvarado-Morales, I. Angelidaki, S. Bastianoni, M. Thomsen (2017)
Seaweed as innovative feedstock for energy and feed – Evaluating the impacts through a Life Cycle AssessmentJournal of Cleaner Production, 150
-
A. Hughes, M. Kelly, K. Black, M. Stanley (2012)
Biogas from Macroalgae: is it time to revisit the idea?Biotechnology for Biofuels, 5
-
Joonhyuk Choi, Jae-wook Choi, D. Suh, Jeong‐Myeong Ha, J. Hwang, H. Jung, Kwan-Young Lee, H. Woo (2014)
Production of brown algae pyrolysis oils for liquid biofuels depending on the chemical pretreatment methodsEnergy Conversion and Management, 86
-
L. Nikolaisen, J. Dahl, J. Busk, M. Rasmussen, A. Bjerre (2011)
Energy Production from Marine Biomass (Ulva lactuca) -
(2008)
The potential of marine biomass for anaerobic biogas production: a feasibility study with recommendations for further research. Scottish Association for Marine Science -
Na Wei, Joshua Quarterman, Yong‐Su Jin (2013)
Marine macroalgae: an untapped resource for producing fuels and chemicals.Trends in biotechnology, 31 2
-
M. Menetrez (2012)
An overview of algae biofuel production and potential environmental impact.Environmental science & technology, 46 13
-
Milla Suutari, E. Leskinen, K. Fagerstedt, J. Kuparinen, P. Kuuppo, J. Blomster (2015)
Macroalgae in biofuel productionPhycological Research, 63
-
E. Kostas, D. White, C. Du, D. Cook (2015)
Selection of yeast strains for bioethanol production from UK seaweedsJournal of Applied Phycology, 28
-
(2015)
pyrolysis of different macroalgae
- Publisher
- Wiley
- Copyright
- © 2018 Wiley Periodicals, Inc.
- ISSN
- 2041-8396
- eISSN
- 2041-840X
- DOI
- 10.1002/wene.288
- Publisher site
- See Article on Publisher Site
Abstract
The following paper provides an overview of the potential uses of seaweeds derived both from artificial cultivation as well as from eutrophic reservoirs as the feedstock for biofuels production. This review presents biochemical (anaerobic digestion [AD] and fermentation), chemical (extraction and transesterification) and thermochemical conversions (combustion, liquefaction, gasification and pyrolysis) of seaweeds for biofuels with special attention being paid to seaweeds processing such as pretreatment techniques, production methods and experimental conditions, and so forth. Seaweeds are considered as a suitable source for biogas and bioethanol production due to their high carbohydrate content. This review explores also the possibility of the application of oil extracted from seaweeds for biodiesel production. Since the chemical composition of seaweeds significantly differs from land biomass, a new comprehensive approach is required. Many macroalgal components are recalcitrant to bioconversion and pose microbiological challenges. The text deals with advantages and disadvantages of seaweeds as a feedstock for biofuels. Since macroalgae exploitation only for energy production is too expensive, seaweed integrated biorefineries were proposed as a solution which enables a development of high‐value algal bioproducts. Algae appear to be a promising source of biofuels. Utilization of waste algal biomass constitutes a link between the pollution abatement and energy production.
Journal
Wiley Interdisciplinary Reviews: Energy and Environment – Wiley
Published: Jan 1, 2018
Keywords: ; ; ; ; ; ; ;