Physical properties of sawdust (i.e. particle size distribution, particle density, porosity, and water retention) from five tropical commercial wood species (Shorealeprosula, Dryobalanops lanceolata, Dipterocarpus cornutus, Shorea laevis, and Eusideroxylon zwageri)  as prepared in various mill types (i.e. handsaw, sawmill, and milling ) were analyzed. This study aims to look into the relationship and interconnected between the use of different mill types, density of wood species origin and physical properties of the resulting sawdust. Generally, different mill types produced sawdust with different particle size distributions. The use of a handsaw produced a higher proportion of oversized particles (OS) and coarser particle size (CPS) than that of sawmill and milling , while also commonly producing the lowest proportion of fine particle size (FPS). For each wood species, the proportion of OS was lower than that of CPS and FPS. In addition, particle density and water retention produced by handsaw in CPS as well as FPS was the smallest, followed in an increasing order sawmill and milling. Porosity of CPS and FPS was the highest in handsaw-cut sawdust, followed in a decreasing order sawmill and milling cut sawdust. This study showed that the different mill types and particle size influenced the physical properties of sawdust. Further, analysis of influential factors on porosity and water retention using General Linear Model revealed that particle density inflicted a strong influence on porosity, as did particle size on water retention.

Afuwape, F.K. 1983. Design and testing of a sawdust compactor. B.Sc. Thesis, Department of Agricultural Engineering. Obafemi Awolowo University, Lie-Ife. Nigeria.

Agnew, J.M. and J.J. Leonard. 2003. The physical properties of compost (Literature Review). Compost Science and Utilization 11: 238-264.

Araki, Y. and M. Terazawa. 2004. Physical properties of sawdust and soil (in Japanese). In: Proceedings of the Hokkaido Branch of Japan Wood Research Society 36, 67-70.

Baker, S.M., T.L. Richard, Z. Zhang and S. Monteiro da Rocha. 1998. Determining the free air space inside compost mixtures using a gas pycnometer. American Society Agricultural Engineering (paper no 984094).

Berg ström, D., S. Israelsson, M. Öhman, S.A Dahlquist, R . Gref, C. Boman and Wästerlund. 2008. Effects of raw material particle size distribution on the characteristics of Scots pine sawdust fuel pellets (Article in press). Fuel Processing Technolog y 6.

Bouma, J., P.S.C. Rao and R .B. Brown. 2003a. Soil as a porous medium: Basics of soil-water relationships-Part I. Reviewed: September 2003 (adopted in July 17,

, University of Florida, IFAS extension, USA. .

Bouma, J., P.S.C. Rao and R .B. Brown. 2003b. Retention of water: Basics of soil-water relationships-Part II. Reviewed : September 2003 (adopted in July 17, 2005), University of Florida, IFAS extension, USA . .

Coudray, N., A. Dieterlen, E. Roth and G. Trouve. 2009. Density measurement of fine aerosol fractions from wood combustion sources using ELPI distributions and image processing techniques. Fuel Processing Technolog y 88: 947-954.

Dikinya, O., C. Hinz and G. Aylmore. 2006. Dispersion and re-deposition of fine particles and their effects on saturated hydraulic conductivity. Australian Journal of Soil Research 44: 47-56.

Frombo, F., R . Minciardi, M. Robba, F. Rosso and Sacile. 2009. Planning woody biomass logistics for energ y production: A strategic decision model. Biomass and Bioenergy 33: 372-83.

Himmel, M., M. Tucker, J. Baker, K. Rivard, and K. Grohmann. 1985. Communition of biomass: hammer and knife mills. In : Proceeding s of Biotechnolog y and Bioengineering Symposium 15.

Horisawa, S., M. Sunagawa, Y. Tamai, Y. Matsuoka, T. Miura and M. Terazawa. 1999. Biodegradation of nonlignocellulosic substances II : Physical and chemical properties of sawdust before and after use as artificial soil. Journal of Wood Science 45: 492-497.

Houghton, J.I., J.E. Burgess and T. Stephenson. 2002. Off-line particle size analysis of digested sludge. Water Resources 36: 4643-4647.

Hwang , S.I., K .P. Lee, D.S. Lee and S.E. Powers. 2002. Models for estimating soil particle-size distributions. Soil Science Society of America Journal 66: 1143-1150.

Johnson, G.R ., B.L. Gartner, D. Maguire and A. Kanaskie. 2003. Influence of bravo fungicide application on wood density and moisture content of Swiss needle cast affected Douglas-fir trees. Forest ecolog y and Management 186: 339-348.

Kitsui, T. and M. Terazawa. 1999. Bio-toilet environmentally-friendly toilets for the 21 century (dry closet using sawdust as an artificial soil matrix). In: Proceedings of international symposium of bio-recycling/composting. 6-8 September, Sapporo, Japan.

MFoR ( The Ministr y of Forestr y Republic of Indonesia). 2007. Forestr y statistics of Indonesia year 2006. Ja kar ta , Indonesia .

Paulrud, S., J.E. Mattsson and C. Nillson. 2002. Particle and handling characteristics of wood fuel powder: effects of different mills. Fuel Processing Technolog y 76: 23-39.

Rühlmann, J., M. Körschens and J. Graefe. 2006. A new approach to calculate the particle density of soils considering properties of the soil organic matter and the mineral matrix. Geoderma 130: 272-283.

SAS Institute Inc. 2007. JMP 7.0.1 Help. SAS Institute Inc, Cary,NC.

Terazawa, M., S. Horisawa, Y. Tamai and K . Yamashita . 1999. Biodegradation of lignocellulosic substance I : System for complete degradation of garbage using sawdust and aerobic soil bacteria. Journal of Wood Science 45: 354-358.

Terazawa, M. 2003. Sawdust Saves Globe - Bioconversion of biomass wastes into multifunctional recyclates using sawdust as an artificial soil matrix. In: Proceedings of the 1st International Symposium on Sustainable Sanitation, Nanjing , China (1): 9-12.

Zavala, M.A.L., N. Funamizu and T. Takakuwa. 2004. Modeling of aerobic biodegradation of feces using sawdust as a matrix. Water Resources 38: 1327-1339.