Radial and longitudinal density variations in Abies cephalonica and Pinus halepensis

doi:10.1007/s11676-022-01521-1

Abstract

Abstract:

Basic wood density is an excellent indicator of quality, it is correlated with numerous physical, physiological and mechanical characteristics of a species and is a good descriptor of wood quality and important indicator of tree performance in community ecology. An accurate method is thus needed to estimate wood density. The standard way is to calculate the ratio of the oven-dried mass of a wood sample divided by its green volume, but wood characteristics within and between growth rings are highly variable; the density can vary in the longitudinal and the radial directions. The present study investigates the longitudinal and radial fluctuations in the basic density of Abies cephalonica Loud and Pinus halepensis Mill. Four logs were cut from four different trees for each species and 16 discs were formed (two discs from each log, one at the base and one at the top). Each disc was cut into cubes where their distance from the pith was measured and then sorted into 2 cm wide concentric zones. The results revealed a mild decreasing trend in basic density from the foot of the trunk upward for both species. The pith in both species also seems to have a relatively high density, which in the immediate next growth rings decreases only to resume increasing toward the bark.

Key words: Aleppo pine, Physical properties, Specific gravity, Wood quality

Vasiliki Dimou, Anna Tsaliki, Kyriaki Kitikidou. Radial and longitudinal density variations in Abies cephalonica and Pinus halepensis[J]. JOURNAL OF FORESTRY RESEARCH, 2023, 34(3): 853-863.

Vasiliki Dimou, Anna Tsaliki, Kyriaki Kitikidou. [J]. 林业研究(英文版), 2023, 34(3): 853-863.

References 45

1	Achard F, Beuchle R, Mayaux P, Stibig H, Bodart C, Brink A, Carbon S, Desclée B, Donnay F, Eva HD, Lupi A, Raši R, Seliger R, Simonetti D. Determination of tropical deforestation rates and related carbon losses from 1990 to 2010. Global Change Biol, 2014, 20: 2540-2554, DOI
2	Breiman L, Friedman JH, Olshen SCJ. Classification and Regression Trees, 1984 New York Chapman & Hall/CRC
3	Chave J (2006) Measuring wood density for tropical forest trees a field manual. U.P.S. Lab. Evolution et Diversité Biologique (ed). https://afritron.org/upload/en/manuals/wood_density_english%5B1%5D.pdf (online publication)
4	Chave J, Coomes D, Jansen S, Lewis SL, Swenson NG, Zanne AE. Towards a worldwide wood economics spectrum. Ecol Lett, 2009, 12: 351-366, DOI
5	Chave J, Muller-Landau HC, Baker TR, Easdale TA, Steege H, Webb CO. Regional and phylogenetic variation of wood density across 2456 neotropical tree species. Ecol Appl, 2006, 16: 2356-2367, DOI
6	Chave J, Andalo C, Brown S, Cairns MA, Chambers JQ, Eamus D, Fölster H, Fromard F, Higuchi N, Kira T, Lescure J, Nelson BW, Ogawa H, Puig H, Riéra B, Yamakura T. Tree allometry and improved estimation of carbon stocks and balance in tropical forests. Oecologia, 2005, 145: 87-99, DOI
7	Cown DJ. Encyclopedia of materials: sci technol (II Edition), 2001 Density Elsevier Ltd Wood 9620-9622, DOI
8	Crous JW, Morris AR, Scholes MC. Effect of phosphorus and potassium fertiliser on stem form, basic wood density and stem nutrient content of Pin us patula at various stem heights. Aust for, 2009, 72: 99-111, DOI
9	Dhaman M. Pinus halepensis: its technological characteristics and utilizations Bulletin D’information. Institut National De Recherches Forestières, Tunisie, 1974, 17: 9-12
10	Dhaman M. Les produits de pind’Alep en Tunisie. CIHEAM, Options Méditerranéennes, aleppo pine products in Tunisia. CIHEAM, Mediterr Options, 1986, 1: 157-161 (in French)
11	Díaz S, Kattge J, Cornelissen JHC, Wright IJ, Lavorel S . Global spectrum of plant form and function. Nature, 2016, 529: 167-171, DOI
12	Dibdiakova J, Vadla K. Basic density and moisture content of coniferous branches and wood in northern norway. Europ Phys J Conf, 2012, DOI
13	Elaieb MT, Shel F, Elouellani S, Janah T, Rahouti M, Thévenon MF, Candelier K. Physical, mechanical and natural durability properties of wood from reforestation Pinus halepensis Mill. in the Mediterranean Basin. Bois For Trop, 2017, 1(331): 19-31, DOI
14	Forest Products Laboratory (2010) Wood handbook-wood as an engeneering material. U S Department of Agriculture Forest Service Forest Products Laboratory FPL-GTR-190 Madison WI 508
15	George JP, Schueler S, Karanitsch-Ackerl S, Mayer K, Klumpp RT, Grabner M (2015) Ιnter- and intra-specific variation in drought sensitivity in Abies spec and its relation to wood density and growth traits. Agric For Meteorol 430–443
16	González-Rodrigo B, Esteban LG, Palacios P, García-Fernández F, Guindeo A. Variation throughout the tree stem in the physical-mechanical properties of the wood of Abies alba Mill from the Spanish Pyrenees. Madera y Bosques, 2013, 19(2): 87-107, DOI
17	Hirai S. Studies on the weightgrowth of forest trees (VI): Chamaecyparisobtusa. Bulletin of the Tokyo Uni Forest, 1958, 54: 199-217
18	ISO 13061–2 (2014) Physical and mechanical propertiesof wood—Test methods for small clear specimens – Part 2: Determination of density for physical and mechanical tests. International Organization for Standardization: 5
19	ISO 4471 (1982) Wood. Sampling sample trees and logs for determination of physical and mechanical properties of wood in homogeneous stands. International Organization for Standardization: 7
20	Jeffers JW. Regression models of variation in specific gravity in four provenances of Sitka spruce. J Inst Wood Sci, 1959, 4: 44-59
21	Koch P. Utilization of the southern pines. USDA Agric Handb, 1972, 420: 1663p
22	Kunstler G, Falster D, Coomes DA, Hui F, Kooyman RM, Laughlin DC, Poorter L, Vanderwel M, Vieilledent G, Wright SJ, Aiba M, Baraloto C, Caspersen J, Cornelissen JH, Gourlet-Fleury S, Hanewinkel M, Herault B, Kattge J, Kurokawa H, Peñuelas P, Poorter H, Uriarte M, Richardson S, Ruiz-Benito P, Sun IF, Ståhl G, Swenson NG, Thompson J, Westerlund B, Wirth C, Zavala MA, Zeng H, Zimmerman JK, Zimmermann NE, Westoby M. Plant functional traits have globally consistent effects on competition. Nature, 2016, 529: 204-207, DOI
23	Lachenbruch B, Moore J, Evans R. Meinzer FC, Lachenbruch B, Dawson TE. Radial variation in wood structure and function in woody plants, and hypotheses for its occurrence. Size and age-related changes in tree structure and function, 2011 Dordrecht Springer
24	Lachenbruch B, McCulloh KA. Traits, properties, and performance: how woody plants combine hydraulic and mechanical functions in a cell, tissue, or whole plant. New Phytol, 2014, 204(4): 747-764, DOI
25	Langbour P, Gérard J, Guibal D, Mahlani K. Technological characterization and development of lumber from Aleppo pine from the Provence-Alpes-Côte d'Azur region. Mediterranean Forest, 2011, 32(3): 263-270 (in French)
26	Liepiņš J, Liepiņš K (2017) Mean basic density and its axial variation in Scots pine, Norway spruce and Birch stems. In: Annual 23rd international scientific conference proceedings, "Research for rural development 2017", volume 1, Jelgava, Latvia, 17–19 May 2017,pp 21–27. 25 https://doi.org/10.22616/rrd.23.2017.003
27	Mason RO, Lind DA, Marchal WG. Statistics: An Introduction, 1983 New York Harcourt Brace Jovanovich Inc 368-383
28	Pan Y, Birdsey RA, Fang J, Houghton R, Kauppi PE, Kurz WA, Phillips OL, Shvidenko A, Lewis SL, Canadell JG, Ciais P, Jackson RB, Pacala SW, McGuire AD, Piao S, Rautiainen A, Sitch S, Hayes D. A large and persistent carbon sink in the world’s forests. Science, 2011, 333: 988-993, DOI
29	Panshin AJ, Zeeuw C. Textbook of wood technology: structure, identification, properties, and uses of the commercial woods of the United States and Canada, 1980 4 New York McGraw-Hill Book Co. 722
30	Pronin D (1971) Estimating tree specific gravity of major pulpwood species of Wisconsin. Forest Service ResearchPaper - FPL 161. Forest Products Laboratory, Madison (WI). p 18
31	Rosner S, Klein A, Müller U, Karlsson B. Hydraulic and mechanical properties of young norway spruce clones related to growth and wood structure. Tree Phys, 2007, 27(8): 1165-1178, PMID: 17472942 DOI
32	Santini NS, Schmitz N, Lovelock CE. Variation in wood density and anatomy in a widespread mangrove species. Trees, 2012, 26: 1555-1563, DOI
33	Saranpää Pekka. Basic density, longitudinal shrinkage and tracheid length of juvenile wood of picea abies(L.) Karst. Scand J Forest Res, 1994, 9(1-4): 68-74, DOI
34	Taylor ER. Interpretation of the correlation coefficient: A basic review. J Diagn Med Sonogr, 1990, 1: 35-39, DOI
35	Taylor FW, Wang EIC, Yanchuk AD, Micko MM. Specific gravity and tracheid length variation of white spruce in Alberta. Can J for Res, 1982, 12: 561-566, DOI
36	Timofeev R (2004) Classification and regression trees (CART) theory and applications. MSc. CASE (Center of Applied Statistics and Economics Humboldt University), Berlin
37	Tsoumis G (1991) Science and technology of wood. New York Van Nostrand Reinhold p 494
38	Vieilledent G, Fischer FJ, Chave J, Guibal D, Langbour P, Gérard J. New formula and conversion factor to compute basic wood density of tree species using a global wood technology database. Am J Bot, 2018, 105(10): 1653-1661, DOI
39	Vieilledent G, Gardi O, Grinand C, Burren C, Andriamanjato M, Camara C, Gardner CJ, Glass L, Rasolohery A, Rakoto Ratsimba H, Gond V, Rakotoarijaona J. Bioclimatic envelope models predict a decrease in tropical forest carbon stocks with climate change in Madagascar. J Ecol, 2016, 104: 703-715, DOI
40	Vieilledent G, Vaudry R, Andriamanohisoa SFD, Rakotonarivo OS, Randrianasolo HZ, Razafindrabe HN, Rakotoarivony CB, Ebeling J, Rasamoelina M. A universal approach to estimate biomass and carbon stock in tropical forests using generic allometric models. Ecol Appl, 2012, 22: 572-583, DOI
41	Violle C, Navas ML, Vile D, Kazakou E, Fortunel C, Hummel I, Garnier E. Let the concept of trait be functional!. Oikos, 2007, 116(5): 882-892, DOI
42	Weber JC. Lamb DR (1970) statistics and research in physical education. St. Louis: CV Mosby Co, 1970, 59–64: 222
43	Westoby M, Wright IJ. Land-plant ecology on the basis of functional traits. Trends Ecol Evol, 2006, 21: 261-268, DOI
44	Zobel BJ, Jett JB. Genetics of wood production, 1995 Berlin Heidelberg Springer, DOI
45	Zobel BJ, Van Buijtenen JP. Wood variation – its causes and control, 1989 Berlin Springer Verlag, DOI