Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis

De, Silma; Pessoa Júnior, Wanison André Gil; Sá, Ingrity S.C.; Takeno, Mitsuo Lopes; Nobre, Francisco Xavier; Pinheiro, William; Manzato, Lizandro; Iglauer, Stefan; Freitas, Flávio A. De

Artigo

Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis

Homogeneous catalysts used for biodiesel synthesis have several limitations, including non-recoverability/reusability, saponification, emulsification, equipment corrosion, and environmental pollution. To overcome these limitations, we synthesized a novel catalyst via calcination of pineapple leaves...

ver descrição completa

Autor principal:	De, Silma
Outros Autores:	Pessoa Júnior, Wanison André Gil, Sá, Ingrity S.C., Takeno, Mitsuo Lopes, Nobre, Francisco Xavier, Pinheiro, William, Manzato, Lizandro, Iglauer, Stefan, Freitas, Flávio A. De
Grau:	Artigo
Idioma:	English
Publicado em:	Bioresource Technology 2020
Assuntos:	Biodiesel Cost Effectiveness Emulsification Fourier transform infrared spectroscopy Methanol Molar ratio Pollution induced corrosion Microscopy, Electron, Scanning Soybean Oil Synthetic fuels Thermogravimetric analysis X ray powder diffraction X rays Biodiesel synthesis Cost effective Environmental Pollutions Homogeneous catalyst Multiple process Novel catalysts Solid base catalysts X ray fluorescence Catalyst Activity Biodiesel Calcium Ion Fossil Fuel Manganese Potassium Alkalinity ash Biofuel Catalysis catalyst chemical alteration Fruit Leaf Methanol Solubility Soybean Alkalinity ash catalyst Cost Effectiveness Analysis Energy Fourier transform infrared spectroscopy fruit waste Nonhuman pineapple Plant Leaf Priority Journal reaction time Recycling Microscopy, Electron, Scanning Synthesis Temperature thermogravimetry Time X-ray Diffraction X ray fluorescence Ananas Comosus Glycine Max en
Acesso em linha:	https://repositorio.inpa.gov.br/handle/1/23267

id	oai:repositorio:1-23267
recordtype	dspace
spelling	oai:repositorio:1-23267 Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis De, Silma Pessoa Júnior, Wanison André Gil Sá, Ingrity S.C. Takeno, Mitsuo Lopes Nobre, Francisco Xavier Pinheiro, William Manzato, Lizandro Iglauer, Stefan Freitas, Flávio A. De Biodiesel Cost Effectiveness Emulsification Fourier transform infrared spectroscopy Methanol Molar ratio Pollution induced corrosion Microscopy, Electron, Scanning Soybean Oil Synthetic fuels Thermogravimetric analysis X ray powder diffraction X rays Biodiesel synthesis Cost effective Environmental Pollutions Homogeneous catalyst Multiple process Novel catalysts Solid base catalysts X ray fluorescence Catalyst Activity Biodiesel Calcium Ion Fossil Fuel Manganese Potassium Alkalinity ash Biofuel Catalysis catalyst chemical alteration Fruit Leaf Methanol Solubility Soybean Alkalinity ash catalyst Cost Effectiveness Analysis Energy Fourier transform infrared spectroscopy fruit waste Nonhuman pineapple Plant Leaf Priority Journal reaction time Recycling Microscopy, Electron, Scanning Synthesis Temperature thermogravimetry Time X-ray Diffraction X ray fluorescence Ananas Comosus Glycine Max en Homogeneous catalysts used for biodiesel synthesis have several limitations, including non-recoverability/reusability, saponification, emulsification, equipment corrosion, and environmental pollution. To overcome these limitations, we synthesized a novel catalyst via calcination of pineapple leaves waste. This catalyst was characterized by X-ray powder diffraction, X-ray fluorescence, Fourier transform infrared spectroscopy, thermogravimetric analysis, scanning electron microscopy, and soluble alkalinity measurements. The catalyst's activity with regards to soybean oil transesterification was analyzed, and multiple process parameters (temperature, catalyst amount, reaction time, and methanol:oil molar ratio) were examined. A high catalytic activity, probably related to the 85 wt% content of alkali/alkali metals (K, Ca and Mg), was observed after a 30 min reaction time, 60 °C, 4 wt% of catalyst, oil to methanol molar ratio of 1:40, reaching an oil to biodiesel conversion above 98%. We conclude that the novel catalyst presented here is efficient, cost-effective, and sustainable, while simultaneously abundant waste is reduced. © 2020 Elsevier Ltd 2020-07-03T21:50:46Z 2020-07-03T21:50:46Z 2020 Artigo https://repositorio.inpa.gov.br/handle/1/23267 10.1016/j.biortech.2020.123569 en Volume 312 Restrito Bioresource Technology
institution	Instituto Nacional de Pesquisas da Amazônia - Repositório Institucional
collection	INPA-RI
language	English
topic	Biodiesel Cost Effectiveness Emulsification Fourier transform infrared spectroscopy Methanol Molar ratio Pollution induced corrosion Microscopy, Electron, Scanning Soybean Oil Synthetic fuels Thermogravimetric analysis X ray powder diffraction X rays Biodiesel synthesis Cost effective Environmental Pollutions Homogeneous catalyst Multiple process Novel catalysts Solid base catalysts X ray fluorescence Catalyst Activity Biodiesel Calcium Ion Fossil Fuel Manganese Potassium Alkalinity ash Biofuel Catalysis catalyst chemical alteration Fruit Leaf Methanol Solubility Soybean Alkalinity ash catalyst Cost Effectiveness Analysis Energy Fourier transform infrared spectroscopy fruit waste Nonhuman pineapple Plant Leaf Priority Journal reaction time Recycling Microscopy, Electron, Scanning Synthesis Temperature thermogravimetry Time X-ray Diffraction X ray fluorescence Ananas Comosus Glycine Max en
spellingShingle	Biodiesel Cost Effectiveness Emulsification Fourier transform infrared spectroscopy Methanol Molar ratio Pollution induced corrosion Microscopy, Electron, Scanning Soybean Oil Synthetic fuels Thermogravimetric analysis X ray powder diffraction X rays Biodiesel synthesis Cost effective Environmental Pollutions Homogeneous catalyst Multiple process Novel catalysts Solid base catalysts X ray fluorescence Catalyst Activity Biodiesel Calcium Ion Fossil Fuel Manganese Potassium Alkalinity ash Biofuel Catalysis catalyst chemical alteration Fruit Leaf Methanol Solubility Soybean Alkalinity ash catalyst Cost Effectiveness Analysis Energy Fourier transform infrared spectroscopy fruit waste Nonhuman pineapple Plant Leaf Priority Journal reaction time Recycling Microscopy, Electron, Scanning Synthesis Temperature thermogravimetry Time X-ray Diffraction X ray fluorescence Ananas Comosus Glycine Max en De, Silma Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis
topic_facet	Biodiesel Cost Effectiveness Emulsification Fourier transform infrared spectroscopy Methanol Molar ratio Pollution induced corrosion Microscopy, Electron, Scanning Soybean Oil Synthetic fuels Thermogravimetric analysis X ray powder diffraction X rays Biodiesel synthesis Cost effective Environmental Pollutions Homogeneous catalyst Multiple process Novel catalysts Solid base catalysts X ray fluorescence Catalyst Activity Biodiesel Calcium Ion Fossil Fuel Manganese Potassium Alkalinity ash Biofuel Catalysis catalyst chemical alteration Fruit Leaf Methanol Solubility Soybean Alkalinity ash catalyst Cost Effectiveness Analysis Energy Fourier transform infrared spectroscopy fruit waste Nonhuman pineapple Plant Leaf Priority Journal reaction time Recycling Microscopy, Electron, Scanning Synthesis Temperature thermogravimetry Time X-ray Diffraction X ray fluorescence Ananas Comosus Glycine Max en
description	Homogeneous catalysts used for biodiesel synthesis have several limitations, including non-recoverability/reusability, saponification, emulsification, equipment corrosion, and environmental pollution. To overcome these limitations, we synthesized a novel catalyst via calcination of pineapple leaves waste. This catalyst was characterized by X-ray powder diffraction, X-ray fluorescence, Fourier transform infrared spectroscopy, thermogravimetric analysis, scanning electron microscopy, and soluble alkalinity measurements. The catalyst's activity with regards to soybean oil transesterification was analyzed, and multiple process parameters (temperature, catalyst amount, reaction time, and methanol:oil molar ratio) were examined. A high catalytic activity, probably related to the 85 wt% content of alkali/alkali metals (K, Ca and Mg), was observed after a 30 min reaction time, 60 °C, 4 wt% of catalyst, oil to methanol molar ratio of 1:40, reaching an oil to biodiesel conversion above 98%. We conclude that the novel catalyst presented here is efficient, cost-effective, and sustainable, while simultaneously abundant waste is reduced. © 2020 Elsevier Ltd
format	Artigo
author	De, Silma
author2	Pessoa Júnior, Wanison André Gil Sá, Ingrity S.C. Takeno, Mitsuo Lopes Nobre, Francisco Xavier Pinheiro, William Manzato, Lizandro Iglauer, Stefan Freitas, Flávio A. De
author2Str	Pessoa Júnior, Wanison André Gil Sá, Ingrity S.C. Takeno, Mitsuo Lopes Nobre, Francisco Xavier Pinheiro, William Manzato, Lizandro Iglauer, Stefan Freitas, Flávio A. De
title	Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis
title_short	Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis
title_full	Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis
title_fullStr	Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis
title_full_unstemmed	Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis
title_sort	pineapple (ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis
publisher	Bioresource Technology
publishDate	2020
url	https://repositorio.inpa.gov.br/handle/1/23267
_version_	1787141520254566400
score	11.755432

Pineapple (Ananás comosus) leaves ash as a solid base catalyst for biodiesel synthesis

Registros relacionados