Kayu jati telah digunakan untuk bermacam produk karena sifat ketahanan alami di atas rata-rata serta keindahan serat dan warna kayunya. Meski demikian, terdapat variasi untuk sifat ketahanan alami di antara pohon yang tumbuh di tempat tumbuh yang berbeda. Penelitian sebelumnya telah mendeskripsikan sifat kimia kayu jati tumbuh di zona ekologis yang berbeda (Nglipar, Panggang, dan Playen). Sebagai lanjutan, penelitian ini bertujuan menentukan sifat ketahahan alami terhadap rayap pada kayu jati yang tumbuh di hutan rakyat Gunungkidul dan mengeksplorasi faktor yang berkorelasi terhadap sifat tersebut yaitu sifat kimia dan warna kayu. Tujuan lainnya adalah membandingkan data yang diperoleh dengan data kayu yang tumbuh di hutan tanaman Perhutani (Randulatung). Uji pengumpanan tanpa pilihan menggunakan rayap tanah Coptotermes curvignathus terhadap sampel kayu dari tiga tempat tumbuh tersebut. Sifat warna tiap sampel diukur dengan sistem diukur menggunakan sistem CIELAB(L*, a*, b*). Data sifat kimia dan warna kemudian dihubungkan dengan kehilangan berat dan persen hidup rayap setelah 13 hari pengumpanan. Kayu gubal dan teras dari semua pohon menunjukkan aktivitas anti rayap. Perbedaan nyata diamati dalam persen hidup dalam interaksi faktor tempat tumbuh dan arah radial pohon. Sampel dari Panggang menunjukkan ketahanan alami yang lebih tinggi didasarkan persen hidup rayapnya. Selanjutnya, bagian teras dari sampel Playen dan Panggang menunjukkan aktivitas anti rayap yang lebih tinggi dibandingkan sampel dari Randublatung. Pengukuran warna menghasilkan tidak adanya beda nyata untuk kecerahan (L*) antara teras bagian luar dan dalam. Berdasar tempat tumbuhnya, sampel Playen memberikan warna kayu yang paling cerah. Apabila data di bagian teras dan gubal digabungkan, nilai kehilangan berat berhubungan positif dengan nilai kelarutan dalam air panas serta nilai kehilangan berat berhubungan negatif dengan nilai kadar ekstraktif etanol-toluena. Selain itu, nilai pH berkorelasi secara moderat dengan persen hidup rayap selama 8 hari pengamatan. Untuk sifat warna, diamati nilai kemerahan (a*) yang semakin tinggi diiringi oleh kenaikan kehilangan berat di bagian teras.

Study of Teakwood Quality from Community Forests in Gunungkidul. VII. Natural Subterranean Termite Resistance

Abstract

Teak wood has been used for various uses because of its excellent natural durability as well as beautiful grain and colour of its heartwood. However, variability in natural durability exists between trees of different geographical zones. The previous paper in this series reported on the chemical properties of teak wood from different zones (Nglipar, Panggang, and Playen). In this study, as a continuation, natural termite resistance of teak wood grown in community forests of Gunungkidul and the factors correlating to the termite resistance i.e. chemical and colour properties, were determined. Further, the data obtained here were compared with that of wood samples from Perhutani forest plantation (Randublatung site). No-choice termite feeding test by using a subterranean termite Coptotermes curvignathus were conducted on wood samples taken from three trees of three planted sites. The colour properties of each sample were measured using the CIELAB (L*, a*, b*) system. The chemical and colour characteristics results then were correlated with the mass loss of wood and survival rate of termites after 13 days of feeding. The heartwood and sapwood of all of the trees tested exhibited antitermitic activities. Significant differences were found in survival rate of termites due to interaction of the site and radial position. Samples from Panggang had larger termite resistance judging by its survival rate of termites. Further, the heartwood regions of Panggang and Playen sites exhibited higher antitermite activities than those of Randublatung samples. Measurements of colour showed that no significant differences were found between outer and inner heartwood parts. Samples from Playen showed the lightest on the basis of the sites. In the combined sapwood and heartwood data, mass loss was positively associated with hot-water solubility levels and negatively with ethanol-toluene extractive content. In addition, pH values moderately correlated with survival rate on 8-day observation. With regard to colour properties, it was measured that larger a* values (redness) induced larger mass loss of heartwood.

Amusant N, Beauchene J, Fournier M, Janin G, Thevenson MF. 2004. Decay resistance in Dicorynia guianensis Amsh.: Analysis of inter-tree and intra-tree variability and relations with wood colour. Annals of Forest Science 61: 373–380.

American Society for Testing and Materials. 2002. Annual book of ASTM Standards. Section four – Construction, Volume 04.10 Wood. West Conshohocken, PA.

Bhat KM, Florence M. 2003. Natural decay resistance of juvenile teak wood grown in high input plantations. Holzforschung 57(5): 453 – 455.

Bhat KM, Thulasidas PK, Maria Florence EJ, Jayaraman K. 2005. Wood durability of home-garden teak against brown-root. Trees 19: 654 – 660.

Browning BL. 1967. Methods of wood chemistry Vol II. Wiley (Interscience). New York.

Burtin P, Jay-Allemand C, Charpentier, Janin G. 1998. Natural wood colouring process in Juglans sp. (J. nigra, J. regia and hybrid J. nigra 23 x J. regia) depends on native phenolic compounds accumulated in the transition zone between sapwood and heartwood. Trees 12: 258 - 264.

Da Costa EWB, Rudman P, Gay FJ. 1958. Investigations on the durability of Tectona grandis. Empirical Forestry Review 37: 291–298.

Fengel D, Wegener G. 1989. Kayu: Kimia, ultrastruktur, reaksi-reaksi. Prawirohatmodjo S, editor. Sastrohamidjojo H, penerjemah.

Gadjah Mada University Press, Jogjakarta Ganapaty S, Thomas PS, Fotso S, Laatsch H. 2004. Antitermitic quinones from Diospyros Sylvatica. Phytochemistry 65: 1265 – 1271.

Gierlinger N, Jacques D, Gardner M, Wimmer R, Schwanninger M, Rozenberg P, Pâques LF. 2004. Colour of larch heartwood and relationships to extractives and brown-rot decay resistance. Trees 18: 102 – 108.

Harju AM, Venalainen M, Anttonen S, Viitanen H, Kainulainen P, Sarapaa P, Vapaavuori E. 2003. Chemical factors affecting the brown-rot decay resistance of Scots pine heartwood. Trees 17:263 – 268.

Hon DNS & Minemura N. 2001. Color and discoloration. Hlm. 385 – 441 dalam Hon DNS, Shiraishi N, editor. Wood and cellulosic chemistry. Marcel Dekker, New York.

Ismayati M, Nakagawa-Izumi A, Kamaluddin NN, Ohi H. 2016. Toxicity and feeding deterrent effect of 2-methylanthraquinone from the wood extractives of Tectona grandis on the subterranean termites Coptotermes formosanus and Reticulitermes speratus. Insects 7:63. doi:10.3390/insects7040063

Kijidani Y, Sakai N, Kimura K, Fujisawa Y, Hiraoka Y, Matsumura J, Koga S. 2012. Termite resistance and color of heartwood of hinoki (Chamaecyparis obtusa) trees in 5 half-sib families in a progeny test stand in Kyushu, Japan. Journal Wood Science 58:471–478.

Kokutse AD, Stokes A, Bailleres H, Kokou K, Baudasse C. 2006. Decay resistance of Togolese teak (Tectona grandis L.) heartwood and relantionship with colour. Trees 20: 219 - 223.

Lukmandaru G. 2009. Sifat kimia dan warna kayu teras jati pada tiga umur berbeda. Jurnal Ilmu dan Teknologi Kayu Tropis 7(1): 1 – 7.

Lukmandaru G. 2011. Variability in the natural termite resistance of plantation teak wood and its relations with wood extractive content and color properties. Journal of Forestry Research 8(1):17-31.

Lukmandaru G. 2013. The natural termite resistance of teak wood grown in community forest. Jurnal Ilmu dan Teknologi Kayu Tropis 11(2): 131-139.

Lukmandaru G. 2015. Quinones distribution of teak wood grown in community forest. Jurnal Ilmu dan Teknologi Kayu Tropis 13(2): 193-204.

Lukmandaru G, Hidayah RN. 2017. Studi mutu kayu jati di hutan rakyat Gunungkidul. VI. Kadar zat anorganik dan keasaman. Jurnal Ilmu Kehutanan 11(1) : 63-75.

Lukmandaru G, Mohammad AR, Wargono P, Prasetyo VE. 2016. Studi mutu kayu jati di hutan rakyat Gunungkidul. V. Sifat kimia kayu. Jurnal Ilmu Kehutanan 10(2): 108-118

Lukmandaru G, Takahashi K. 2008. Variation in the natural termite resistance of teak (Tectona grandis Linn. fil.) wood as a function of tree age. Annals of Forest Science 65(7): 708 p1-p8.

Lukmandaru G, Takahashi K. 2009. Radial distribution of quinones in plantation teak (Tectona grandis L.f.). Annals of Forest Science 66(6): 605 p1 – p9.

Lukmandaru G, Ogiyama K. 2005. Bioactive compounds from ethyl acetate extract of teakwood (Tectona grandis L.f.). Hlm. 346-350. Proceedings of the 6th International Wood Science Symposium LIPI-JSPS Core, Bali.

Marsoem SN. 2013. Studi mutu kayu jati di hutan rakyat Gunungkidul. I. Pengukuran laju pertumbuhan. Jurnal Ilmu Kehutanan 7(2):108-122.

Marsoem SN, Prasetyo VE, Sulistyo J, Sudaryono, Lukmandaru G. 2014a. Studi mutu kayu jati di hutan rakyat Gunungkidul. III. Sifat fisika kayu. Jurnal Ilmu Kehutanan 8(2):76-89.

Marsoem SN, Prasetyo VE, Sulistyo J, Sudaryono, Lukmandaru G. 2014b. Studi mutu kayu jati di hutan rakyat Gunungkidul. II. Pengukuran tegangan pertumbuhan. Jurnal Ilmu Kehutanan 8(1):3-13.

Marsoem SN, Prasetyo VE, Sulistyo J, Sudaryono, Lukmandaru G. 2015. Studi mutu kayu jati di hutan rakyat Gunungkidul. IV. Sifat mekanika kayu. Jurnal Ilmu Kehutanan 9(2):117-127.

Moya R, Berrocal A. 2010. Wood colour variation in sapwood and heartwood of young trees of Tectona grandis and its relationship with plantation characteristics, site, and decay resistance. Annals of Forest Science 67: 109.

Nandika D, Adijuwana H. 1995. Ekstraksi enzim selulase dari rayap kayukering Cryptotermes cynocephalus Light serta rayap tanah Coptotermes curvignathus Holmgren serta Macrotermes gilvus Hagen. Jurnal Teknologi Hasil Hutan 8(1):35-40.

Narayanamurti D, George J, Pant HC, Singh J. 1962. Extractive in teak. Silvae Genetica 11(3): 57 – 63.

Ngee P, Tashiro A, Yoshimura T, Jaal Z, Lee C. 2004. Wood preference of selected Malaysian subterranean termites (Isoptera: Rhinotermitidae, Termitidae). Sociobiology 43(3): 535 – 550.

Niamké FB, Amusant N, Charpentier JP, Chaix G, Baissac Y, Boutahar N, Adima AA, Coulibaly SK, Allemand CJ. 2011. Relationships between biochemical attributes (non-structural carbohydrates and phenolics) and natural durability against fungi in dry teak wood (Tectona grandis L. f.). Annals of Forest Science 68:201-211.

Rowell R, Pettersen R, Han JS, Rowell JS, Tshabalala MS. 2005. Cell wall chemistry. Hlm. 50 dalam Rowell R,editor. Handbook of wood chemistry and wood composites. CRC Press. Boca Raton-London-New York- Washington D.C.

Rudman P, Da Costa EWB, Gay FJ. 1966. Wood quality in plus trees of teak (Tectona grandis L.f.). Sylvae Genetica 16: 102 – 105.

Shmulsky R & Jones PD. 2011. Forest Products and Wood Science: An Introduction, Sixth Edition. John Wiley & Sons, Inc.

Taylor AM, Gartner BL, Morell JJ. 2002. Heartwood formation and natural durability – A review. Wood and Fiber Science 34(4): 587-611.

Technical Association for the Pulp and Paper Industries. 1992. TAPPI Test Method T 222 os-74. TAPPI Press. Atlanta.

Wilkins AP, Stamp CM. 1990. Relationship between wood colour, silvicultural treatment and rate of growth in Eucalyptus grandis Hill (Maiden). Wood Science and Technology 24:297 - 304.

Windeisen E, Klassen A, Wegener G. 2003. On the chemical characterisation of plantation teakwood from Panama. Holz als Roh- und Werkstoff 61: 416 – 418.