Abstract

Near infrared spectroscopic examination of charred pine wood, bark, cellulose and lignin: implications for the quantitative determination of charcoal in soils

James B. Reeves, III
Environmental Management and Byproduct Utilization Laboratory, Bulding 306, Room 101, Beltsville Agricultural Research Centre East, Beltsville, Maryland 20705, USA. E-mail: james.reeves@ars.usda.gov,
Gregory W. McCarty
Hydrology and Remote Sensing Laboratory, Building 007, Room 120, Beltsville Agricultural Research Centre West, Beltsville, Maryland 20705, USA
David W. Rutherford and Robert L. Wershaw
US Geological Survey, MS 408, PO Box 25046, Denver Federal Centre, Denver, CO 80225, USA

The objective of this research was to investigate the effect of charring on near infrared spectra of materials likely to be present in forest fires in order to determine the feasibility of determining charred carbon in soils. Four materials (cellulose, lignin, pine bark and pine wood) and char from these materials created by charring for various durations (1 to 168 h) and at various temperatures (200 to 450°C) were studied. Near infrared spectra and measures of acidity (total acids, carboxylic acids, lactones and phenols as determined by titration) were available for 56 different samples (Not all samples charred at all temperatures/durations). Results showed spectral changes that varied with the material, temperature and duration of charring. Examination of spectra and correlation plots indicated that changes in the constituents of the materials in question, such as loss of OH groups in carbohydrates, rather than direct determination of typical products produced by charring, such as carboxylic acids, lactones and phenols, were the basis for the spectral changes. Finally, while the spectral changes resulting from charring appeared to be relatively unique to each material, PLS calibrations for total acids, carboxylic acids, lactones and phenols were successfully created (with R² of 0.991, 0.943, 0.931 and 0.944, respectively) indicating that there is a sufficient commonality in the changes to develop calibrations without the need for unique calibrations for each specific set of charring conditions (i.e. material, temperature and time of heating).

Keywords: NIR spectroscopy, near infrared, charred, charcoal, soil, wood, bark, lignin, cellulose, carbon

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