BirkettM.D. and GambinoM.J.T., “Potential applications for near infrared spectroscopy in the pulping industry”, Paper Southern Africa November/December, 34–38 (1988).
2.
BirkettM.D. and GambinoM.J.T., “Estimation of pulp kappa number with near-infrared reflectance spectroscopy”, Tappi J.72, 193–197 (1989).
3.
WrightJ.A.BirkettM.D. and GambinoM.J.T., “Prediction of pulp yield and cellulose content from wood samples using near-infrared reflectance spectroscopy”, Tappi J.73, 164–166 (1990).
4.
WallbåcksL.EdlundU.NordénB. and IversenT., “Multivariate characterization of pulp, Part 1. Spectroscopic characterization of physical and chemical differences between pulps using C CP/MAS NMR, FTIR, NIR and multivariate data analysis”, Nordic Pulp Paper Res. J.2, 74–80 (1991). doi: https://dx-doi-org.web.bisu.edu.cn/10.3183/NPPRJ-1991-06-02-p074-080
5.
WallbåcksL.EdlundU.NordénB.IversenT. and MohlinU.-B., “Multivariate characterisation of pulp. Part 2. Interpretation and prediction of beating processes”, Nordic Pulp Paper Res. J.3, 104–109 (1991). doi: https://dx-doi-org.web.bisu.edu.cn/10.3183/NPPRJ-1991-06-03-p104-109
6.
WallbåcksL.EdlundU.NordénB. and BerglundI., “Multivariate characterization of pulp using solid-state 13C NMR, FTIR, and NIR”, Tappi J.74, 201–206 (1991).
7.
MederR.GallagherS.KimberleyM.O.UprichardJ.M. and MackieK.L., “Prediction of wood chip and pulp and paper properties via multivariate analysis of spectral data”, Proceedings 64th Appita Conference, Melbourne, Australia, pp. 479–484 (1994).
8.
MichellA.J., “Pulpwood quality estimation by near-infrared spectroscopic measurements on eucalypt woods”, Appita J.48, 425–428 (1995).
9.
MichellA.J. and SchimleckL.R., “NIR spectroscopy of woods from Eucalyptus globulus”’Appita J.49, 23–26 (1996).
10.
EastyD.B.BerbenS.A.De ThomasF.A. and BrimmerP.J., “Near-infrared spectroscopy for the analysis of wood pulping: Quantifying hardwood-softwood mixtures and estimating lignin content”, Tappi J.73, 257–261 (1990).
11.
TsuchikawaS.HayashiK. and TsutsumiS., “Application of near infrared spectrophotometry to wood. 1. Effects of the surface-structure”, Mokuzai Gakkaishi38, 128–136 (1992).
12.
TsuchikawaS. and TsutsumiS., “Application of near infrared spectrophotometry to wood. 2. Behaviour of irradiated light in an aggregate of tracheids, and directional characteristics of diffuse reflected and transmitted light”, Mokuzai Gakkaishi42, 343–353 (1996).
13.
TsuchikawaS.HayashiK. and TsutsumiS., “Nondestructive measurement of the subsurface structure of biological material having cellular structure by using near-infrared spectroscopy”, Appl. Spectrosc.50, 1117–1124 (1996). doi: https://dx-doi-org.web.bisu.edu.cn/10.1366/0003702963905114
14.
HoffmeyerP. and PedersenJ.G., “Evaluation of density and strength of Norway spruce wood by near-infrared reflectance spectroscopy”’Holz als Roh und Werkstoff53, 165–170 (1995). doi: https://dx-doi-org.web.bisu.edu.cn/10.1007/BF02716418
15.
ThummA. and MederR., “Stiffness prediction of radiata pine clearwood test pieces using near infrared spectroscopy”, J. Near Infrared Spectrosc.9, 117–122 (2001). doi: https://dx-doi-org.web.bisu.edu.cn/10.1255/jnirs.298
16.
SchimleckL.R.EvansR. and IlicJ., “Application of near infrared spectroscopy to a diverse range of species demonstrating wide density and stiffness variation”, IAWA Journal22, 415–429 (2001). doi: https://dx-doi-org.web.bisu.edu.cn/10.1163/22941932-90000386
17.
SchimleckL.R. and EvansR., “Estimation of air-dry density of increment cores by near infrared spectroscopy”, Appita J.56, 312–317 (2003).
18.
ViaB.K.ShupeT.F.GroomL.H.StineM. and SoC.-L., “Multivariate modelling of density; strength and stiffness from near infrared spectra for mature, juvenile and pith wood of longleaf pine (Pinus palustris)”, J. Near Infrared Spectrosc.11, 365–378 (2003). doi: https://dx-doi-org.web.bisu.edu.cn/10.1255/jnirs.388
LestanderT.A. and RhenC., “Multivariate NIR spectroscopy models for moisture; ash and calorific content in biofuels using biorthogonal partial least square regression”, Analyst130, 1182–1189 (2005). doi: https://dx-doi-org.web.bisu.edu.cn/10.1039/b500103j
TrungT.DownesG.M.MederR. and AllisonB., “Pulp mill and chemical recovery control with advanced analysers – from trees to final product”, Appita J.68, 39–46 (2015).
25.
GindlW.TeischingerA.SchwanningerM. and HinterstoisserB., “The relationship between near infrared spectra of radial wood surfaces and wood mechanical properties”, J. Near Infrared Spectrosc.9, 255–261 (2001). doi: https://dx-doi-org.web.bisu.edu.cn/10.1255/jnirs.311
26.
MederR.ThummA. and MarstonD., “Sawmill trial of at-line prediction of recovered lumber stiffness by NIR spectroscopy of Pinus radiata cants”, J. Near Infrared Spectrosc.11, 137–143 (2003). doi: https://dx-doi-org.web.bisu.edu.cn/10.1255/jnirs.361
KoboriH.InagakiT.FujimotoT.OkuraT. and TsuchikawaS., “Fast online NIR technique to predict MOE and moisture content of sawn lumber”, Holzforschung69, 329–335 (2014).
29.
BailleresH.DavrieusF. and PichavantF.H., “Near infrared analysis as a tool for rapid screening of some major wood characteristics in a eucalyptus breeding program”, Annals Forest Sci.59, 479–490 (2002). doi: https://dx-doi-org.web.bisu.edu.cn/10.1051/forest:2002032
MederR.BrawnerJ.T.DownesG.M. and EbdonN., “Towards the in-forest analysis of Kraft pulp yield: Comparing the in-laboratory performance of laboratory and handheld instruments and their value in screening breeding trials”, J. Near Infrared Spectrosc.19, 421–429 (2011). doi: https://dx-doi-org.web.bisu.edu.cn/10.1255/jnirs.954
32.
WarburtonP.BrawnerJ.T. and MederR., “Handheld NIR spectroscopy for the prediction of leaf physiological status in tree seedlings”, J. Near Infrared Spectrosc.22, 433–438 (2014). doi: https://dx-doi-org.web.bisu.edu.cn/10.1255/jnirs.1137
