Abstract
The objective of this research was to calibrate and compare the ability of near infrared (NIR) and Fourier transform infrared reflectance (FT-IR) to predict strand density. Four hundred and fifty flakes were randomly selected, measured for density, and then 99 flakes (33 = low, 33 = medium and 32 = high density) were selected for calibration and cross-validation through the predicted sum of squares (PRESS) method. This research found that calibration equations from NIR spectra (R2 = 0.82; RMSEP=0.059 g cm−3) was superior to equations developed from FT-IR (R2 = 0.68; RMSEP=0.076 g cm−3) when the same number of factors were used. Using a first-derivative pre-treatment, five factors were necessary to predict strand density from NIR spectra despite a random tracheid (wood cell) orientation. Lignin-associated wavelengths (range, 1660–1670 nm) provided the most leverage in predicting strand density although crystalline and amorphous components of cellulose also played a role. The prediction of density above 0.65 g cm−3 was inaccurate for both NIR- and FT-IR-based models. The bias was attributable to the additional absorbance that occurred at higher densities.
© 2010 IM Publications LLP
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