Modeling Microfibril Angle and Tree Age in Acacia mangium Wood Using X-Ray Technique

Tabet A. Tamer; Fauziah Abdul Aziz; Noraini Abdulla

doi:10.4028/www.scientific.net/AMR.620.496

Paper Titles

Fabrication of Nanoporous Aluminum Oxide via a Two-Step Anodisation Process
p.464

Fundamental Characterisation of Dredged Marine Sediments from Kuala Perlis Jetty by XRF, XRD and FTIR
p.469

Properties of Aluminium Thin Films on Polyimide Plastics as Back Contacts in Thin Film Silicon Solar Cells
p.474

Quantitative Energy Dispersive X-Ray Flourescence Analysis of Low Alloy Steel by Regression and Modified Fundamental Parameter Techniques
p.480

Pb(Zr_0.52Ti_0.48)O₃ Ceramics Synthesized Using Planetary Ball Mill
p.486

Dehydration Studies of Biomass Resources for Activated Carbon Production Using BET and XRD Techniques
p.491

Modeling Microfibril Angle and Tree Age in Acacia mangium Wood Using X-Ray Technique
p.496

Characteristics of Airborne Pm_2.5 and Pm_2.5-10 in the Urban Environment of Kuala Lumpur
p.502

The Effects of Superheating Treatment on Distribution of Eutectic Silicon Particles in A357-Continuous Stainless Steel Composite
p.511

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 620Modeling Microfibril Angle and Tree Age in Acacia...

Modeling Microfibril Angle and Tree Age in Acacia mangium Wood Using X-Ray Technique

Abstract:

The term microfibril angle (MFA) in wood refers to the angle between the spiralling cellulose fibrils and the long axis of the tracheid cell wall. Diffraction patterns arising from crystal planes of various sample forms of wood trees had attracted scientific research in determining the crystallographic measurements. As such the tropical hard wood in Sabah, Acacia mangium was chosen for experimental data. Age-contributing factors were measured; the angle of reflection (θ), relative intensity, full width at half maximum (FWHM), the nearest between two neighbouring atoms in the crystalline structure (d-spacing) and the peak height, had been taken into account at different ages, pith and bark of tree. Regressions were done in comparing the microfibril angle, MFA at different ages using the least-square method and cubic-spline interpolation. The latter was able to interpolate a polynomial up to the third order. The range of the optimum angle was found to have benefited foresters in deciding the time for tree cropping and harvesting.

You might also be interested in these eBooks

Advanced X-Ray Characterization Techniques

View Preview

Info:

Periodical:

Advanced Materials Research (Volume 620)

Pages:

496-501

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.620.496

Citation:

Cite this paper

Online since:

December 2012

Authors:

Tabet A. Tamer, Fauziah Abdul Aziz, Noraini Abdulla

Keywords:

Crystallographic Factors, Interpolation, Microfibril Angle, Optimum Angle, Regression Model

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] L.A. Jozsaand and G. R Middleton: Canada special publication No. SP-34 (1994).

Google Scholar

[2] G.K. Elliot: Technical Communication No. 8, Commonwealth Forestry Bureau: Oxford, England (1970).

Google Scholar

[3] Anon: The Encyclopaedia Of Wood. Sterling publishing Co., Inc. New York (1980).

Google Scholar

[4] I.D. Cave and J.F.C. Walker: Forest Product Journal. Vol. 44(5) (1994), pp.43-48.

Google Scholar

[5] Addis, Tsehaye, A.H. Buchanan and J.C.F. Walker: Journal of Institute of Wood Science Vol. 13(5) (1995), pp.513-518.

Google Scholar

[6] H.L. Mitchell and M.P. Denne: Forestry Vol. 70(1) (1997).

Google Scholar

[7] J.D. Brazier and R.S. Howell: Forestry Vol. 52(2) (1979), pp.177-185.

Google Scholar

[8] J.G. Haygreenand and J.L. Bowyer: Forest Product and Wood Science (An Introduction). 3rd Edition (1996), p.490.

Google Scholar

[9] J.A. Petty, D.C. Macmillan and C.M. Steward 1990: Forestry Vol. 63(1), pp.39-49.

Google Scholar

[10] L.A. Donaldson: New Zealand Journal of Forestry Science. Vol. 25(2) (1993), pp.164-174.

Google Scholar

[11] J.C.F. Walker and B.G. Butterfield: New Zealand Forestry (1996) 34-40.

Google Scholar

[12] M. Treacy, J. Evertsen and Á.N. Dhubháin: A Comparison of Mechanical & Physical Wood Properties of a Range of Sitka spruce Provenances. Processing Products No. 1 Extract from Coford final report publication. Coford, Diblin, Ireland (2001).

Google Scholar