Deoxygenation of microalgal oil into hydrocarbon with precious metal catalysts: Optimization of reaction conditions and supports

Deoxygenation of microalgal oil obtained by pyrolysis of microalgae was carried out for the production of hydrocarbon fuel from biomass by metal supported catalyst. Oleic acid was used as a model reactant to select an optimized catalyst. Effects of support, metal species, and metal loading on cataly...

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Published in:	Energy (Oxford) Vol. 47; no. 1; pp. 25 - 30
Main Authors:	Na, Jeong-Geol, Yi, Bo Eun, Han, Jun Kyu, Oh, You-Kwan, Park, Jong-Ho, Jung, Tae Sung, Han, Sang Sup, Yoon, Hyung Chul, Kim, Jong-Nam, Lee, Hyunjoo, Ko, Chang Hyun
Format:	Journal Article Conference Proceeding
Language:	English
Published:	Kidlington Elsevier Ltd 01-11-2012 Elsevier
Subjects:	Activated carbon Applied sciences biomass boiling point Catalysis Catalysts catalytic activity Chlorella Decarboxylation Deoxygenation Energy Exact sciences and technology fuels Hydrocarbons Microalgae oils Oleic acid oxygen Platinum Pyrolysis Pyrolysis oil silica temperature transportation Pyrolysis oil Microalgae Platinum Oleic acid Decarboxylation Deoxygenation
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Abstract	Deoxygenation of microalgal oil obtained by pyrolysis of microalgae was carried out for the production of hydrocarbon fuel from biomass by metal supported catalyst. Oleic acid was used as a model reactant to select an optimized catalyst. Effects of support, metal species, and metal loading on catalytic performance were investigated. Activated carbon showed better performance than silica as a support. Considering various factors in model reaction, such as metal loading, reaction temperature, activity for deoxygenation, and selectivity for decarboxylation, 5wt% platinum supported on activated carbon (5wt% Pt/C) was selected as an optimized catalyst. Based on these results, deoxygenation of the pyrolysis oil from Chlorella sp. KR-1 was conducted at 623 and 673K over this selected catalyst. The product after catalytic deoxygenation was mainly composed of pure hydrocarbons, and its oxygen content was below 2.0%. The fraction in the product of which the boiling point was less than 623K was about 90%. These properties could allow this upgraded oil to be used for transportation fuel. However, the degree of oxygen removal with microalgal pyrolysis oil was lower than that with oleic acid, implying that impurities in the pyrolysis oil may inhibit the deoxygenation reaction. ▸ For the transportation fuels production, deoxygenation of pyrolysis oil from microalgae using precious metal catalysts was investigated. ▸ The optimized catalyst for the dexoygenation of model reactant, oleic acid, was 5wt% Pt/C. ▸ The optimized catalyst, 5wt% Pt/C, showed reasonable catalytic activity for the deoxygenation of pyrolysis oil.
AbstractList	Deoxygenation of microalgal oil obtained by pyrolysis of microalgae was carried out for the production of hydrocarbon fuel from biomass by metal supported catalyst. Oleic acid was used as a model reactant to select an optimized catalyst. Effects of support, metal species, and metal loading on catalytic performance were investigated. Activated carbon showed better performance than silica as a support. Considering various factors in model reaction, such as metal loading, reaction temperature, activity for deoxygenation, and selectivity for decarboxylation, 5wt% platinum supported on activated carbon (5wt% Pt/C) was selected as an optimized catalyst. Based on these results, deoxygenation of the pyrolysis oil from Chlorella sp. KR-1 was conducted at 623 and 673K over this selected catalyst. The product after catalytic deoxygenation was mainly composed of pure hydrocarbons, and its oxygen content was below 2.0%. The fraction in the product of which the boiling point was less than 623K was about 90%. These properties could allow this upgraded oil to be used for transportation fuel. However, the degree of oxygen removal with microalgal pyrolysis oil was lower than that with oleic acid, implying that impurities in the pyrolysis oil may inhibit the deoxygenation reaction. Deoxygenation of microalgal oil obtained by pyrolysis of microalgae was carried out for the production of hydrocarbon fuel from biomass by metal supported catalyst. Oleic acid was used as a model reactant to select an optimized catalyst. Effects of support, metal species, and metal loading on catalytic performance were investigated. Activated carbon showed better performance than silica as a support. Considering various factors in model reaction, such as metal loading, reaction temperature, activity for deoxygenation, and selectivity for decarboxylation, 5 wt% platinum supported on activated carbon (5 wt% Pt/C) was selected as an optimized catalyst. Based on these results, deoxygenation of the pyrolysis oil from Chlorella sp. KR-1 was conducted at 623 and 673 K over this selected catalyst. The product after catalytic deoxygenation was mainly composed of pure hydrocarbons, and its oxygen content was below 2.0%. The fraction in the product of which the boiling point was less than 623 K was about 90%. These properties could allow this upgraded oil to be used for transportation fuel. However, the degree of oxygen removal with microalgal pyrolysis oil was lower than that with oleic acid, implying that impurities in the pyrolysis oil may inhibit the deoxygenation reaction. Deoxygenation of microalgal oil obtained by pyrolysis of microalgae was carried out for the production of hydrocarbon fuel from biomass by metal supported catalyst. Oleic acid was used as a model reactant to select an optimized catalyst. Effects of support, metal species, and metal loading on catalytic performance were investigated. Activated carbon showed better performance than silica as a support. Considering various factors in model reaction, such as metal loading, reaction temperature, activity for deoxygenation, and selectivity for decarboxylation, 5wt% platinum supported on activated carbon (5wt% Pt/C) was selected as an optimized catalyst. Based on these results, deoxygenation of the pyrolysis oil from Chlorella sp. KR-1 was conducted at 623 and 673K over this selected catalyst. The product after catalytic deoxygenation was mainly composed of pure hydrocarbons, and its oxygen content was below 2.0%. The fraction in the product of which the boiling point was less than 623K was about 90%. These properties could allow this upgraded oil to be used for transportation fuel. However, the degree of oxygen removal with microalgal pyrolysis oil was lower than that with oleic acid, implying that impurities in the pyrolysis oil may inhibit the deoxygenation reaction. ▸ For the transportation fuels production, deoxygenation of pyrolysis oil from microalgae using precious metal catalysts was investigated. ▸ The optimized catalyst for the dexoygenation of model reactant, oleic acid, was 5wt% Pt/C. ▸ The optimized catalyst, 5wt% Pt/C, showed reasonable catalytic activity for the deoxygenation of pyrolysis oil.
Author	Park, Jong-Ho Kim, Jong-Nam Na, Jeong-Geol Yoon, Hyung Chul Han, Jun Kyu Han, Sang Sup Lee, Hyunjoo Ko, Chang Hyun Jung, Tae Sung Oh, You-Kwan Yi, Bo Eun
Author_xml	– sequence: 1 givenname: Jeong-Geol surname: Na fullname: Na, Jeong-Geol organization: Clean Fuel Research Center Korea Institute of Energy Research, Daejeon, 305-343, South Korea – sequence: 2 givenname: Bo Eun surname: Yi fullname: Yi, Bo Eun organization: Clean Fuel Research Center Korea Institute of Energy Research, Daejeon, 305-343, South Korea – sequence: 3 givenname: Jun Kyu surname: Han fullname: Han, Jun Kyu organization: Clean Fuel Research Center Korea Institute of Energy Research, Daejeon, 305-343, South Korea – sequence: 4 givenname: You-Kwan surname: Oh fullname: Oh, You-Kwan organization: Clean Fuel Research Center Korea Institute of Energy Research, Daejeon, 305-343, South Korea – sequence: 5 givenname: Jong-Ho surname: Park fullname: Park, Jong-Ho organization: Clean Fuel Research Center Korea Institute of Energy Research, Daejeon, 305-343, South Korea – sequence: 6 givenname: Tae Sung surname: Jung fullname: Jung, Tae Sung organization: Clean Fuel Research Center Korea Institute of Energy Research, Daejeon, 305-343, South Korea – sequence: 7 givenname: Sang Sup surname: Han fullname: Han, Sang Sup organization: Clean Fuel Research Center Korea Institute of Energy Research, Daejeon, 305-343, South Korea – sequence: 8 givenname: Hyung Chul surname: Yoon fullname: Yoon, Hyung Chul organization: Clean Fuel Research Center Korea Institute of Energy Research, Daejeon, 305-343, South Korea – sequence: 9 givenname: Jong-Nam surname: Kim fullname: Kim, Jong-Nam organization: Clean Fuel Research Center Korea Institute of Energy Research, Daejeon, 305-343, South Korea – sequence: 10 givenname: Hyunjoo surname: Lee fullname: Lee, Hyunjoo organization: Department of Chemical and Biomolecular Engineering, Yonsei University, Seoul, 120-749, South Korea – sequence: 11 givenname: Chang Hyun surname: Ko fullname: Ko, Chang Hyun email: chko514@gmail.com, chko@jnu.ac.kr organization: School of Applied Chemical Engineering, Chonnam National University, Gwangju 500-767, South Korea
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Snippet	Deoxygenation of microalgal oil obtained by pyrolysis of microalgae was carried out for the production of hydrocarbon fuel from biomass by metal supported...
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SubjectTerms	Activated carbon Applied sciences biomass boiling point Catalysis Catalysts catalytic activity Chlorella Decarboxylation Deoxygenation Energy Exact sciences and technology fuels Hydrocarbons Microalgae oils Oleic acid oxygen Platinum Pyrolysis Pyrolysis oil silica temperature transportation
Title	Deoxygenation of microalgal oil into hydrocarbon with precious metal catalysts: Optimization of reaction conditions and supports
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