Raman Spectroscopy for Characterizing Porous carbon

Amdani, Rima Zuriah

Raman Spectroscopy for Characterizing Porous carbon

Mark

Amdani, Rima Zuriah ^LU (2020) FYSU60 20201
Department of Physics
Combustion Physics

Abstract: Porous carbon obtained from low cost and abundant biomass has gained attention as renewable material feedstock. In this study, porous carbon biochar produced through pyrolysis was investigated by Raman spectroscopy to disclose the structural properties. The measured samples were in form of pellets (identified as WP, 139, 233, 226), and lumber wood (Pine, a softwood type and Beech, a hardwood type). The resulted spectra, which consisted of two broadened overlapped peaks were fitted with two Gaussian curves. The intensity ratio of the curves (ID/IG) were calculated to analyse the aromaticity of the samples. The aromaticity represents the proportion of the total C phases (amorphous and crystalline) within the samples. The result indicates... (More); Porous carbon obtained from low cost and abundant biomass has gained attention as renewable material feedstock. In this study, porous carbon biochar produced through pyrolysis was investigated by Raman spectroscopy to disclose the structural properties. The measured samples were in form of pellets (identified as WP, 139, 233, 226), and lumber wood (Pine, a softwood type and Beech, a hardwood type). The resulted spectra, which consisted of two broadened overlapped peaks were fitted with two Gaussian curves. The intensity ratio of the curves (ID/IG) were calculated to analyse the aromaticity of the samples. The aromaticity represents the proportion of the total C phases (amorphous and crystalline) within the samples. The result indicates that the aromaticity of the samples increased as the pyrolysis temperature was raised. Furthermore, the biochar obtained for higher temperature had larger crystalline surface area, which is indicated by La (crystalline length). The La values obtained were around 9-10 Å and exhibit a highly disordered structure with turbostratic arrangement. As complementary, the data from Raman measurements were also compared with elemental analysis results to show the amount of carbon content in the samples. The results from elemental analysis present that the higher temperature will produce higher carbon proportion in the samples. Thereby, both Raman spectroscopy and elemental analysis give similar trends for evaluating the structure of the samples. In comparison with a soot sample, biochar exhibits less carbonization since the aromaticity and crystalline surface area (defined by La) of the soot have higher values. The Raman signal increases for higher laser power and detector integration acquisition time. However, high power and long acquisition time promote fluorescence background. Thus, moderate laser power and integration time was preferably chosen for reliable Raman measurements. (Less)

Please use this url to cite or link to this publication: http://lup.lub.lu.se/student-papers/record/9020903

author

Amdani, Rima Zuriah ^LU

supervisor

Christian Brackmann ^LU
Frederik Ossler ^LU

organization

course

FYSU60 20201

year

2020

type

H1 - Master's Degree (One Year)

subject

keywords

Raman Spectroscopy, Porous Carbon, Biochar, Carbonization, Aromaticity

language

English

id

9020903

date added to LUP

2020-07-02 21:38:43

date last changed

2020-07-02 21:38:43

@misc{9020903,
  abstract     = {{Porous carbon obtained from low cost and abundant biomass has gained attention as renewable material feedstock. In this study, porous carbon biochar produced through pyrolysis was investigated by Raman spectroscopy to disclose the structural properties. The measured samples were in form of pellets (identified as WP, 139, 233, 226), and lumber wood (Pine, a softwood type and Beech, a hardwood type). The resulted spectra, which consisted of two broadened overlapped peaks were fitted with two Gaussian curves. The intensity ratio of the curves (ID/IG) were calculated to analyse the aromaticity of the samples. The aromaticity represents the proportion of the total C phases (amorphous and crystalline) within the samples. The result indicates that the aromaticity of the samples increased as the pyrolysis temperature was raised. Furthermore, the biochar obtained for higher temperature had larger crystalline surface area, which is indicated by La (crystalline length). The La values obtained were around 9-10 Å and exhibit a highly disordered structure with turbostratic arrangement. As complementary, the data from Raman measurements were also compared with elemental analysis results to show the amount of carbon content in the samples. The results from elemental analysis present that the higher temperature will produce higher carbon proportion in the samples. Thereby, both Raman spectroscopy and elemental analysis give similar trends for evaluating the structure of the samples. In comparison with a soot sample, biochar exhibits less carbonization since the aromaticity and crystalline surface area (defined by La) of the soot have higher values. The Raman signal increases for higher laser power and detector integration acquisition time. However, high power and long acquisition time promote fluorescence background. Thus, moderate laser power and integration time was preferably chosen for reliable Raman measurements.}},
  author       = {{Amdani, Rima Zuriah}},
  language     = {{eng}},
  note         = {{Student Paper}},
  title        = {{Raman Spectroscopy for Characterizing Porous carbon}},
  year         = {{2020}},
}

LUP Student Papers

LUND UNIVERSITY LIBRARIES

Raman Spectroscopy for Characterizing Porous carbon