An abundant porous biochar material derived from wakame (Undaria pinnatifida) with high adsorption performance for three organic dyes

[Display omitted] •A one-step pyrolysis/activation method was used to prepare wakame biochar (AWBM).•AWBM has abundant mesopores with a high specific surface area (1156.25 m2/g).•At 293 K, the adsorption of MG using AWBM can reach 4066.96 mg/g.•The adsorption of dyes using AWBM contain physical and...

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Published inBioresource technology Vol. 318; no. C; p. 124082
Main Authors Yao, Xinxin, Ji, Lili, Guo, Jian, Ge, Shaoliang, Lu, Wencheng, Chen, Yingna, Cai, Lu, Wang, Yaning, Song, Wendong
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 01.12.2020
Elsevier
Subjects
Abundant porous structure
activated carbon
Adsorption
Adsorption mechanism
biochar
Charcoal
Coloring Agents
endothermy
heat treatment
Kinetics
malachite green
Methylene Blue
Organic dyes
Porosity
porous media
rhodamines
sorption isotherms
Spectroscopy, Fourier Transform Infrared
thermodynamics
Undaria
Undaria pinnatifida
Wakame biochar
wastewater treatment
Water Pollutants, Chemical
Abundant porous structure
Organic dyes
Adsorption mechanism
Wakame biochar
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Abstract [Display omitted] •A one-step pyrolysis/activation method was used to prepare wakame biochar (AWBM).•AWBM has abundant mesopores with a high specific surface area (1156.25 m2/g).•At 293 K, the adsorption of MG using AWBM can reach 4066.96 mg/g.•The adsorption of dyes using AWBM contain physical and chemical adsorption. In this study, an activated wakame biochar material (AWBM) was prepared by a one-step calcination and activation method, whose adsorption performances for methylene blue (MB), Rhodamine B (RB) and malachite green (MG) were also analyzed. The results showed AWBM was a mesoporous fluffy structure material with a higher specific surface (1156.25 m2/g), exhibiting superior adsorption capacities for MB (841.64 mg/g), RB (533.77 mg/g) and MG (4066.96 mg/g), respectively. In addition, FT-IR analysis showed that AWBM possessed abundant active groups (such as –OH, –CO and –CH), further enhancing the adsorption efficiencies. The Langmuir model could better fit the three dyes adsorption isotherms process using AWBM, and the Pseudo-second-order model could better describe the adsorption kinetic experimental data. The thermodynamic analysis showed that the three dyes adsorption using AWBM was spontaneous endothermic reaction. This study suggests AWBM has enormous potential in the application of removing organic dyes from wastewater.
AbstractList In this study, an activated wakame biochar material (AWBM) was prepared by a one-step calcination and activation method, whose adsorption performances for methylene blue (MB), Rhodamine B (RB) and malachite green (MG) were also analyzed. The results showed AWBM was a mesoporous fluffy structure material with a higher specific surface (1156.25 m2/g), exhibiting superior adsorption capacities for MB (841.64 mg/g), RB (533.77 mg/g) and MG (4066.96 mg/g), respectively. In addition, FT-IR analysis showed that AWBM possessed abundant active groups (such as -OH, -CO and -CH), further enhancing the adsorption efficiencies. The Langmuir model could better fit the three dyes adsorption isotherms process using AWBM, and the Pseudo-second-order model could better describe the adsorption kinetic experimental data. The thermodynamic analysis showed that the three dyes adsorption using AWBM was spontaneous endothermic reaction. This study suggests AWBM has enormous potential in the application of removing organic dyes from wastewater.In this study, an activated wakame biochar material (AWBM) was prepared by a one-step calcination and activation method, whose adsorption performances for methylene blue (MB), Rhodamine B (RB) and malachite green (MG) were also analyzed. The results showed AWBM was a mesoporous fluffy structure material with a higher specific surface (1156.25 m2/g), exhibiting superior adsorption capacities for MB (841.64 mg/g), RB (533.77 mg/g) and MG (4066.96 mg/g), respectively. In addition, FT-IR analysis showed that AWBM possessed abundant active groups (such as -OH, -CO and -CH), further enhancing the adsorption efficiencies. The Langmuir model could better fit the three dyes adsorption isotherms process using AWBM, and the Pseudo-second-order model could better describe the adsorption kinetic experimental data. The thermodynamic analysis showed that the three dyes adsorption using AWBM was spontaneous endothermic reaction. This study suggests AWBM has enormous potential in the application of removing organic dyes from wastewater.
In this study, an activated wakame biochar material (AWBM) was prepared by a one-step calcination and activation method, whose adsorption performances for methylene blue (MB), Rhodamine B (RB) and malachite green (MG) were also analyzed. The results showed AWBM was a mesoporous fluffy structure material with a higher specific surface (1156.25 m /g), exhibiting superior adsorption capacities for MB (841.64 mg/g), RB (533.77 mg/g) and MG (4066.96 mg/g), respectively. In addition, FT-IR analysis showed that AWBM possessed abundant active groups (such as -OH, -CO and -CH), further enhancing the adsorption efficiencies. The Langmuir model could better fit the three dyes adsorption isotherms process using AWBM, and the Pseudo-second-order model could better describe the adsorption kinetic experimental data. The thermodynamic analysis showed that the three dyes adsorption using AWBM was spontaneous endothermic reaction. This study suggests AWBM has enormous potential in the application of removing organic dyes from wastewater.
[Display omitted] •A one-step pyrolysis/activation method was used to prepare wakame biochar (AWBM).•AWBM has abundant mesopores with a high specific surface area (1156.25 m2/g).•At 293 K, the adsorption of MG using AWBM can reach 4066.96 mg/g.•The adsorption of dyes using AWBM contain physical and chemical adsorption. In this study, an activated wakame biochar material (AWBM) was prepared by a one-step calcination and activation method, whose adsorption performances for methylene blue (MB), Rhodamine B (RB) and malachite green (MG) were also analyzed. The results showed AWBM was a mesoporous fluffy structure material with a higher specific surface (1156.25 m2/g), exhibiting superior adsorption capacities for MB (841.64 mg/g), RB (533.77 mg/g) and MG (4066.96 mg/g), respectively. In addition, FT-IR analysis showed that AWBM possessed abundant active groups (such as –OH, –CO and –CH), further enhancing the adsorption efficiencies. The Langmuir model could better fit the three dyes adsorption isotherms process using AWBM, and the Pseudo-second-order model could better describe the adsorption kinetic experimental data. The thermodynamic analysis showed that the three dyes adsorption using AWBM was spontaneous endothermic reaction. This study suggests AWBM has enormous potential in the application of removing organic dyes from wastewater.
In this study, an activated wakame biochar material (AWBM) was prepared by a one-step calcination and activation method, whose adsorption performances for methylene blue (MB), Rhodamine B (RB) and malachite green (MG) were also analyzed. The results showed AWBM was a mesoporous fluffy structure material with a higher specific surface (1156.25 m²/g), exhibiting superior adsorption capacities for MB (841.64 mg/g), RB (533.77 mg/g) and MG (4066.96 mg/g), respectively. In addition, FT-IR analysis showed that AWBM possessed abundant active groups (such as –OH, –CO and –CH), further enhancing the adsorption efficiencies. The Langmuir model could better fit the three dyes adsorption isotherms process using AWBM, and the Pseudo-second-order model could better describe the adsorption kinetic experimental data. The thermodynamic analysis showed that the three dyes adsorption using AWBM was spontaneous endothermic reaction. This study suggests AWBM has enormous potential in the application of removing organic dyes from wastewater.
ArticleNumber 124082
Author Wang, Yaning
Guo, Jian
Lu, Wencheng
Chen, Yingna
Ge, Shaoliang
Yao, Xinxin
Cai, Lu
Song, Wendong
Ji, Lili
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  fullname: Ji, Lili
  email: jll-gb@163.com
  organization: Institute of Innovation & Application, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China
– sequence: 3
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  surname: Guo
  fullname: Guo, Jian
  organization: College of Food and Medical, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China
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  givenname: Shaoliang
  surname: Ge
  fullname: Ge, Shaoliang
  organization: College of Port and Transportation Engineering, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China
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  fullname: Chen, Yingna
  organization: College of Food and Medical, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China
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  surname: Wang
  fullname: Wang, Yaning
  organization: Institute of Innovation & Application, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China
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  givenname: Wendong
  surname: Song
  fullname: Song, Wendong
  organization: College of Petrochemical and Energy Engineering College, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China
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Issue C
Keywords Abundant porous structure
Organic dyes
Adsorption mechanism
Wakame biochar
Language English
License Copyright © 2020 Elsevier Ltd. All rights reserved.
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Snippet [Display omitted] •A one-step pyrolysis/activation method was used to prepare wakame biochar (AWBM).•AWBM has abundant mesopores with a high specific surface...
In this study, an activated wakame biochar material (AWBM) was prepared by a one-step calcination and activation method, whose adsorption performances for...
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StartPage 124082
SubjectTerms Abundant porous structure
activated carbon
Adsorption
Adsorption mechanism
biochar
Charcoal
Coloring Agents
endothermy
heat treatment
Kinetics
malachite green
Methylene Blue
Organic dyes
Porosity
porous media
rhodamines
sorption isotherms
Spectroscopy, Fourier Transform Infrared
thermodynamics
Undaria
Undaria pinnatifida
Wakame biochar
wastewater treatment
Water Pollutants, Chemical
Title An abundant porous biochar material derived from wakame (Undaria pinnatifida) with high adsorption performance for three organic dyes
URI https://dx.doi.org/10.1016/j.biortech.2020.124082
https://www.ncbi.nlm.nih.gov/pubmed/32932115
https://www.proquest.com/docview/2443521717
https://www.proquest.com/docview/2552020899
https://www.osti.gov/biblio/2279898
Volume 318
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