Variation of Growth and Genetics Parameters of Acacia auriculiformis Second-Generation Progeny Trial at KHDTK Playen, Indonesia

Open Access

Issue		BIO Web Conf. Volume 167, 2025 5^th International Conference on Smart and Innovative Agriculture (ICoSIA 2024)


Article Number		06008
Number of page(s)		8
Section		Smart Genetics Resource Management and Utilization
DOI		https://doi.org/10.1051/bioconf/202516706008
Published online		19 March 2025

Badan Pusat Statistik. Statistik Produksi Kehutanan Statistics of Forestry Production 2022. (Badan Pusat Statistik, Jakarta, 2022). [Google Scholar]
Boland D. J., Pinyopusarerk K., McDonald M. W., Jovanovic T., and Booth TH. The Habitat of Acacia auriculiformis and Probable Factors Associated with its Distribution. J. of Trop. For. Sci. 3, 159–180. (1990). [Google Scholar]
Haque, M. M., Ni, Y., Akon, A. J. U., Quaiyyum, M. A., and Jahan, M. S. A Review on Acacia auriculiformi s: Importance as Pulpwood Planted in Social Forestry. Inter. Wood Prod. Jour. 12, 194–205.(2021). https://doi.org/10.1080/20426445.2021.1949107 [Google Scholar]
Sushardi. Kualitas Kayu Lapis dari Kombinasi Kayu Akasia (Acacia auriculiformis) dan Sungkai (Peronema canescens). J. Hut. Trop. 10, 35–45. (2015). DOI: 10.36873/iht.v10i01.64 [Google Scholar]
Kataki, R., and Konwer, D. Fuelwood Characteristics of Indigenous Tree Species of North-East India. Biomass and Bioenergy. 22(6), 433–437. (2002). https://doi.org/10.1016/S0961-9534(02)00026-0 [Google Scholar]
Chakraborty, L., Pandit, P., and Maulik, S. R. Acacia auriculiformis - A Natural Dye Used for Simultaneous Coloration and Functional Finishing on Textiles. J. of Cleaner Prod. 245, 118921. (2020). https://doi.org/10.1016/j.jclepro.2019.118921 [Google Scholar]
Shukla, S. R., Rao, R. V., Sharma, S. K., Kumar, P., Sudheendra, R., and Shashikala, S. Physical and Mechanical Properties of Plantation-Grown Acacia auriculiformis of Three Different Ages. Aus. For. 70(2), 86–92. (2007). https://doi.org/10.1080/00049158.2007.10675007 [Google Scholar]
Hounlonon, M. C., Kouchade, C. A., and Kounouhewa, B. B. Physical and Mechanical Properties of Acacia auriculiformis A. Cunningham Ex Benth Used as Timber in Benin. J. of Mat. Sci. and Surf. Eng. 8(1), 992–1000. (2021). https://doi.org/10.52687/2348-8956/815 [Google Scholar]
Barry, K. M., Mihara, R., Davies, N. W., Mitsunaga, T., & Mohammed, C. L. Polyphenols in Acacia mangium and Acacia auriculiformis heartwood with reference to heart rot susceptibility. J. Wood Sci. 51(6):65–621.(2005). https://doi.org/10.1007/s10086-005-0707-x [Google Scholar]
Duong, D. V., Schimleck, L., Tran, D. L., & Vo, H. D. Radial and Among-clonal Variations of the Stress-wave Velocity, Wood Density, and Mechanical Properties in 5-year-old Acacia auriculiformis Clones. BioResources, 17(2). (2022). DOI: 10.15376/biores.17.2.2084-2096 [Google Scholar]
Shukor, N. A. A., Awang, K., Rashid, M. M., dan Senin, A. L. Provenance Trial of Acacia auriculiformis in Peninsular Malaysia: 12 - Month Performance. J. of Trop. For. Sci. 6(3), 249–256. (1992). [Google Scholar]
Barbosa, M. C., Street, J., Owens, F. C., & Shmulsky, R. The effect of multiple knots in close proximity on southern pine lumber properties. For. Prod. Jour. 69(4), 278–282. (2019). DOI: 10.13073/FPJ-D-19-00027 [Google Scholar]
Wright, S., Dahlen, J., Montes, C., & Eberhardt, T. L. Quantifying knots by image analysis and modeling their effects on the mechanical properties of loblolly pine lumber. European J. of Wood and Wood Prod. 77, 903–917. (2019). https://doi.org/10.1007/s00107-019-01441-8 [Google Scholar]
Cao, Y., Street, J., & Li M. Evaluation of the effect of knots on rolling shear strength of cross laminated timber (CLT). Const. and Build. Mat. 222, 579–587. (2019). https://doi.org/10.1016/j.conbuildmat.2019.06.165 [Google Scholar]
As, N., Goker, Y., & Dundar, T. Effect of Knots on the physical and mechanical properties of scots pine. Wood Res. 51(3), 51–58. (2006). [Google Scholar]
Dinwoodie, J. M. Timber: its nature and behavior. (Taylor and Francis, Abingdon, Unite Kingdom, 2000). [Google Scholar]
Lin, W., Wang, J., Wu, J., & DeVallance, D. Log sawing practices and lumber recovery of small hardwood sawmills in West Virginia. For. Prod. J. 61(3), 216–224. (2011). DOI: 10.13073/0015-7473-61.3.216 [Google Scholar]
Acuna, M. A., & Murphy, G. E. Estimating relative log prices of Douglas-fir through a financial analysis of the effects of wood density on lumber recovery and pulp yield. For. Prod. J. 57(3), 60. (2007). [Google Scholar]
Luangviriyasaeng, V. & Pinyopusarerk, K. Genetic Variation in A Second-Generation Progeny Trial of Acacia auriculiformis in Thailand. J. of Trop. For. Sci. 14(1), 131–144. (2002). [Google Scholar]
Susanto, M., Prayitno, T. A. & Fujisawa, Y. Wood Genetic Variation of Acacia auriculiformis at Wonogiri Trial in Indonesia. J. of For. Res. 5(2), 135–145. (2008). [Google Scholar]
Handayani, B. R., Kartikaningtyas, D., Setyaji, T., Sunarti, S., and Nirsatmanto, A. Keragaman Genetik Jenis Introduksi Acacia auriculiformis pada Uji Keturunan Generasi Kedua di Gunungkidul, Yogyakarta, in Prosiding Seminar Nasional Masyarakat Biodiversitas Indonesia, Surakarta, April 6 (2018). [Google Scholar]
Resende, R. T., Silva, P. I. T., Silva-Junior, O. B., Freitas, M. L. M., Sebbenn, A. M., Sousa, V. A., de Aguiar, A. V. & Grattapaglia, D. Age trends in genetic parameters for growth performance across country-wide provenances of the iconic conifer tree Araucaria angustifolia show strong prospects for systematic breeding and early selection. For. Eco. and Man. 501, 119671. (2021). https://doi.org/10.1016/j.foreco.2021.119671 [CrossRef] [Google Scholar]
Tonouewa, J. F. M. F., Langbour, P., Biaou, S. S. H., Assede, E. S., Guibal, D., Kouchade, C. A., & Kounouhewa, B. B. Anatomical and physico- mechanical properties of Acacia auriculiformis wood in relation to age and soil in Benin, West Africa. Eur. J. of Wood and Wood Prod. 78, 745–756. (2020). https://doi.org/10.1007/s00107-020-01540-x [Google Scholar]
Nirsatmanto A, Sunarti S, Setyaji T, and Surip. General Information of Seed Source (F-2) Establisment of Acacia auriculiformis in Gunungkidul, Yogyakarta. Forestry Research and Development Agency (FORDA). Ministry of Forestry in Indonesia, Jakarta. (2015). [Google Scholar]
Zobel B. J., and Talbert J. T. Applied Forest Tree Improvement. (John Wiley and Sons, New York, 1984). [Google Scholar]
Lee, S. H., Kim, D. H., Jeong, J. H., Han, S. H., Kim, S., Park, H. J., & Kim, H. J. Developing a yield table and analyzing the economic feasibility for Acacia hybrid plantations in achieving carbon neutrality in southern Vietnam. Forests. 13(8), 1316. (2022). https://doi.org/10.3390/f13081316 [CrossRef] [Google Scholar]
Hadiyan, Y. & Leksono, B. Variasi Pertumbuhan Tanaman pada Uji Provenansi Acacia crassicarpa Umur 9 Tahun di Lipat Kain, Riau. J. Pem. Tan. Hut. 1, 101–110. (2003). [Google Scholar]
Ghosh, S. R., Wadud, M. A., Mondol, M. A., & Rahman, G. M. M. Optimization of plant density of Akashmoni (Acacia auriculiformis) for production of fuel wood in the bunds of crop land. J. of Agro. and Env. 5(2), 1–6. (2011). [Google Scholar]
Ali, M. S., Malimbwi, R. E., & Iddi, S. Comparison of Volume Production, Basic Density and Stem Quality Between Acacia mangium and Acacia auriculiformis Grown in Zanzibar. J. of Trop. For. Sci. 10(1), 10–17. (1997). http://www.jstor.org/stable/43582187 [Google Scholar]
Weber, J. C., Montes, C. S., Cornelius, J., & Ugarte, J. Genetic variation in tree growth, stem form and mortality of in slower-and faster-growing plantations in the Peruvian Amazon. Silvae Genetica. 60(1-6), 70–78. (2011). DOI: https://doi.org/10.1515/sg-2011-0010 [Google Scholar]
Kohlstock, N., & Schneck, H. Scots pine (Pinus sylvestris L.) breeding at Waldsieversdorf and its impact on pine management in northern Germany lowlands. Silvae Genet. 41, 174–180. (1992). [Google Scholar]
Krusche, D., Das, B. L., & Stephan, B. R. Results of a progeny test with Pinus sylvestris and estimation of genetic gains from different selection methods. Silvae Genet. 29, 122–129. (1980). [Google Scholar]
Adinugraha, H. A., Pudjiono, S., Ismail, B., & Mahfudz, M. Plant Growth Variation at Combined Progeny and Provenance Of 5-Year-Old Intsia bijuga (Colebr.) O. Kuntze in Sobang, Banten. Jurnal Wasian. Vol. 1(2), 65–72. (2014). [Google Scholar]
Sutrisno, L. Pendugaan Nilai Heritabilitas pada Tegakan Uji Keturunan Acacia mangium Willd Generasi Kedua di Parungpanjang, Bogor. Thesis, Institut Pertanian Bogor, 2007. [Google Scholar]
Kartikaningtyas, D., Setyaji, T., & Nirsatmanto, A. Volume Tegakan Acacia mangium pada Uji Perolehan Genetik dengan Kerapatan Tegakan Tinggi. J. Pem. Tan. Hut. 11(2), 113–122. (2017). [CrossRef] [Google Scholar]
Suhartati, Rahmayanto, Y., & Daeng, Y. Dampak Penurunan Daur Tanaman HTI Acacia terhadap Kelestarian Produksi, Ekologis, dan Sosial. Info Teknis Eboni. 11(2), 103–116. (2014). [Google Scholar]
Na’iem, M. Pemuliaan Pohon: Konsep Dasar, Penggunaan Materi Genetik Unggul, dan Pembangunan Hutan Prospektif. (Karima Jaya Media, Sleman, 2022). [Google Scholar]
Susanto, M., Baskorowati, L., & Setiadi, D. Estimasi Peningkatan Genetik Falcataria moluccana di Cikampek, Jawa Barat. J. Pen. Hut. Tan. 11, 65–76. (2014). [CrossRef] [Google Scholar]
Wright, J. W. Introduction to Forest Genetics. (Academic Press, New York, 1976). [Google Scholar]
Cotterill P.P., and Dean CA. Successful Tree Breeding with Index Selection. (CSIRO-Division of Forestry and Forest Product, Melbourne, 1990). [Google Scholar]
Dey, T., Ahmed, S., & Islam, M. A. Relationships of tree height-diameter at breast height (DBH) and crown diameter-DBH of Acacia auriculiformis plantation. Asian J. of For. 5(2), 71–75. (2021). https://doi.org/10.13057/asianjfor/r050203 [CrossRef] [Google Scholar]
Luechanimitchit, P., Luangviriyasaeng, V., Laosakul, S., Pinyopusarerk, K., & Bush, D. Genetic parameter estimates for growth, stem-form and branching traits of Casuarina junghuhniana clones grown in Thailand. Forest Ecology and Management. 404, 251–257. (2017). https://doi.org/10.1016/j.foreco.2017.08.030 [Google Scholar]

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