Bromine number prediction for Colombian naphthas using near-infrared spectroscopy and chemometric methods

Bromine number prediction for Colombian naphthas using near-infrared spectroscopy and chemometric methods

Thirty-eight naphtha samples were used to develop a chemometric method to predict bromine number. All samples were characterized by Fourier transform near infrared spectroscopy (FT-NIR), and their spectra were correlated by similarity using principal component analysis (PCA). The models for bromine...

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Main Authors: Carlos Aparicio, Jader Guerrero, Rafael Cabanzo, Enrique Mejía-Ospino
Format: Article
Language:English
Published: Universidad Industrial de Santander 2016-12-01
Series:Revista Ion
Subjects:
FT-NIR
naphtha
bromine number
PCA
PLS
MPR
Online Access:http://revistas.uis.edu.co/index.php/revistaion/article/view/5985/6262
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spelling doaj-98b9d32225bd4baf8dd157f9f35a25192020-11-24T22:16:28ZengUniversidad Industrial de SantanderRevista Ion0120-100X2145-84802016-12-012927585Bromine number prediction for Colombian naphthas using near-infrared spectroscopy and chemometric methodsCarlos AparicioJader Guerrero0Rafael Cabanzo1Enrique Mejía-Ospino2Universidad Industrial de SantanderUniversidad Industrial de SantanderUniversidad Industrial de SantanderThirty-eight naphtha samples were used to develop a chemometric method to predict bromine number. All samples were characterized by Fourier transform near infrared spectroscopy (FT-NIR), and their spectra were correlated by similarity using principal component analysis (PCA). The models for bromine number determination (BN) were established by Partial Least Squares regression (PLS) and Multiple Polynomial Regression (MPR). PCA allowed classifying the samples into the light and heavy, determining the most significant spectral variables. These variables are located in the regions between 4000-4800 and 5200-6350cm-1. The results determined by combining FT-NIR spectroscopy and chemometrics were very close to those obtained by standardized methods. This approach may be an alternative for analysis of BN, which requires sample turnarounds lower than five minutes and lower cost compared to traditional methods.http://revistas.uis.edu.co/index.php/revistaion/article/view/5985/6262FT-NIRnaphthabromine numberPCAPLSMPR
collection DOAJ
language English
format Article
sources DOAJ
author Carlos Aparicio
Jader Guerrero
Rafael Cabanzo
Enrique Mejía-Ospino
spellingShingle Carlos Aparicio
Jader Guerrero
Rafael Cabanzo
Enrique Mejía-Ospino
Bromine number prediction for Colombian naphthas using near-infrared spectroscopy and chemometric methods
Revista Ion
FT-NIR
naphtha
bromine number
PCA
PLS
MPR
author_facet Carlos Aparicio
Jader Guerrero
Rafael Cabanzo
Enrique Mejía-Ospino
author_sort Carlos Aparicio
title Bromine number prediction for Colombian naphthas using near-infrared spectroscopy and chemometric methods
title_short Bromine number prediction for Colombian naphthas using near-infrared spectroscopy and chemometric methods
title_full Bromine number prediction for Colombian naphthas using near-infrared spectroscopy and chemometric methods
title_fullStr Bromine number prediction for Colombian naphthas using near-infrared spectroscopy and chemometric methods
title_full_unstemmed Bromine number prediction for Colombian naphthas using near-infrared spectroscopy and chemometric methods
title_sort bromine number prediction for colombian naphthas using near-infrared spectroscopy and chemometric methods
publisher Universidad Industrial de Santander
series Revista Ion
issn 0120-100X
2145-8480
publishDate 2016-12-01
description Thirty-eight naphtha samples were used to develop a chemometric method to predict bromine number. All samples were characterized by Fourier transform near infrared spectroscopy (FT-NIR), and their spectra were correlated by similarity using principal component analysis (PCA). The models for bromine number determination (BN) were established by Partial Least Squares regression (PLS) and Multiple Polynomial Regression (MPR). PCA allowed classifying the samples into the light and heavy, determining the most significant spectral variables. These variables are located in the regions between 4000-4800 and 5200-6350cm-1. The results determined by combining FT-NIR spectroscopy and chemometrics were very close to those obtained by standardized methods. This approach may be an alternative for analysis of BN, which requires sample turnarounds lower than five minutes and lower cost compared to traditional methods.
topic FT-NIR
naphtha
bromine number
PCA
PLS
MPR
url http://revistas.uis.edu.co/index.php/revistaion/article/view/5985/6262
work_keys_str_mv AT carlosaparicio brominenumberpredictionforcolombiannaphthasusingnearinfraredspectroscopyandchemometricmethods
AT jaderguerrero brominenumberpredictionforcolombiannaphthasusingnearinfraredspectroscopyandchemometricmethods
AT rafaelcabanzo brominenumberpredictionforcolombiannaphthasusingnearinfraredspectroscopyandchemometricmethods
AT enriquemejiaospino brominenumberpredictionforcolombiannaphthasusingnearinfraredspectroscopyandchemometricmethods
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