Combining parallel factor analysis and machine learning for the classification of dissolved organic matter according to source using fluorescence signatures

Autor: S. M. McConnell, Chad W. Cuss, Céline Guéguen
Rok vydání: 2016
Předmět:
Environmental Engineering
010504 meteorology & atmospheric sciences
Health
Toxicology and Mutagenesis
Decision tree
Chemical Fractionation
010501 environmental sciences
Machine learning
computer.software_genre
01 natural sciences
Fluorescence
Machine Learning
Rivers
Dissolved organic carbon
Environmental Chemistry
Organic matter
Organic Chemicals
Ecosystem
0105 earth and related environmental sciences
chemistry.chemical_classification
Single model
Chemistry
business.industry
Public Health
Environmental and Occupational Health
General Medicine
General Chemistry
Models
Theoretical
Linear discriminant analysis
Pollution
6. Clean water
Plant Leaves
Support vector machine
Spectrometry
Fluorescence
Multilayer perceptron
Neural Networks
Computer
Artificial intelligence
Factor Analysis
Statistical
business
computer
Water Pollutants
Chemical
Environmental Monitoring
Zdroj: Chemosphere. 155:283-291
ISSN: 0045-6535
Popis: Parallel factor (PARAFAC) analysis of dissolved organic matter (DOM) fluorescence has facilitated a surge of investigation into its biogeochemical cycling. However, rigorous, PARAFAC-based methods for holistically distinguishing DOM sources are lacking. This study classified 1029 PARAFAC-analyzed excitation-emission matrices (EEMs) measured using DOM isolated from 24 different leaf leachates, rivers, and organic matter standards using four machine learning methods (MLM). EEMs were also divided into subsets to assess the impact of experimental treatments (i.e. whole EEMs, size fractionation, mixtures, quenching) and dataset properties (i.e. different numbers of EEMs from each leachate/river) on classification. A split-half validated, 10-component PARAFAC model was extended to 12 components to remove consistent peaks evident in model residuals. The 12-component model performed better than the 10-component model, correctly classifying up to 80 additional EEMs, when the dataset included size-fractionated DOM or several different sources (i.e. many leaf species and rivers); however, the 10-component model performed better for whole-sample EEMs when comparing leaf leachates to rivers. The MLM correctly classified whole EEMs of riverine DOM by source with up to 87.0% accuracy, leachates with up to 92.5% accuracy, and distinguished leachates from rivers with 97.2% accuracy. A difference of up to 17.3% in classification accuracy was observed depending on the MLM method used with the following order: multilayer perceptron = support vector machine > k-nearest neighbours ≫ decision tree; however, performances differed widely depending on the data subset. Classification accuracy for whole and size-fractionated rivers compared to whole and size-fractionated leachates using N-way partial least-squares discriminant analysis (NPLS-DA; 97.7%) was similar to that achieved using MLM. Combining MLM with PARAFAC is an effective method for classifying DOM based on its fluorescence signature because PARAFAC can isolate meaningful fluorescent species and unlike PLSDA, MLM constructs a single model which simultaneously classifies EEMs as belonging to one of several categories. A complete accounting of carbon flows through ecosystems should include the processes and sources that contribute to the disparate fluorescence signatures of riverine and leached DOM.
Databáze: OpenAIRE
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