Canopy interception on tree architecture models of aubreville, stone and leeuwenberg in Lore Lindu National Park Area, Indonesia

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Research Paper 01/02/2017
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Canopy interception on tree architecture models of aubreville, stone and leeuwenberg in Lore Lindu National Park Area, Indonesia

Naharuddin, Ariffien Bratawinata, Sigit Hardwinarto, Ramadanil Pitopang
J. Bio. Env. Sci.10( 2), 75-88, February 2017.
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Abstract

An important component in the hydrological cycle is vegetation, especially its role in intercept rainfall. This study aims to determine the effect of rainfall on the throughfall, stem flow and canopy interception on  Aubreville architectural models, Leeuwenberg and Stone tree stands. This research conducted at the forest garden land of Gumbasa sub watershed, in Palu watershed. Administratively the region is in districtof Gumbasa, Sigi Regency, Central Sulawesi Province, which is included in the Lore Lindu National Park Area. Determination of the sample conducted representatively, using the survey method by way of the path along the river at Gumbasa Sub watershed. Data were analyzed using statistical analysis through a simple linear regression equation. The results showed that the relationship between rainfall to stem flow, throughfall, and canopy interception is linear and highly significant at the level of 99%. The best architectural trees model to increase the amount of water up to the ground surface is the Leeuwenberg model of species Calophyllum soulattri (Clusiaceae).

VIEWS 80

Arcova FCS, V de Cicco, PAB Rocha. 2003. Precipitação efetiva e interceptação das chuvas por floresta de mata atlântica em uma microbacia experimental em Cunha, São Paulo. Revista Árvore 27(2), 257-262

Arijani. 2006. Korelasi Model Arsitektur Pohon Dengan Laju Aliran Batang,Curahan Tajuk, Infiltrasi, Aliran Permukaan dan Erosi (Suatu studi tentang peranan vegetasi dalam konservasi tanah dan air pada sub-DAS Cianjur Cisokan Citarum Tengah). Disertasi (unpublished). Program Pasca Sarjana, Institut Pertanian Bogor.

Asdak C. 2004. Hidrologi dan Pengelolaan Daerah Aliran Sungai. Gadjah Mada University Press. Yogyakarta.

Asdak C, Jarvis PG, Van Gardingen P, Fraser A.1998. Rainfall interception loss in unlogged and logged forest areas of Central Kalimantan, Indonesia. Journal of Hydrology 206, 237-244.

Aththorick TA. 2000. Pengaruh Model Arsitektur Pohon Massart dan Rauh terhadap Aliran Batang, Curahan Tajuk, Aliran Permukaan dan Erosi di Hutan Pendidikan Gunung Walat Sukabumi. Tesis (unpublished). Program Pascasarjana Institut Pertanian Bogor.

Brandt J. 1987. The effect of different types of forest management on the transformation of rainfall energy by the canopy in relation to soil erosion. In: Proceedings of the Forest Hydrology Watershed Management Conference. Vancouver, BC IAHS Publication 167, 213–222

Bruijnzeel LA. 1990. Hydrology of moist tropical forest and effects of conversion:A stage of knowledge review. UNESCO International Hydrological Programme & Free University, Amsterdam.

Calux J, Thomaz El. 2012. Interceptação e Precipitação Interna: Comparação Entre Floresta Ombrófila Mista e Pinus elliotttii var. elliotti. Revista Eletrônica do Curso de Geografia, Jataí 19, 24-39.

Chen YY, Ming HL. 2016. Quantifying Rainfall Interception Loss of a Subtropical Broadleaved Forest in Central Taiwan. Journal Water 8(1), 1-19.

Chairani S,Dan Jayanti DS. 2013. Intersepsi Curah Hujan Pada Tegakan Pohon Pinus (Casuarina cunninghamia). Jurnal Rona Teknik Pertanian 6(1), 405-412

Chanpaga U,Dan Watchirajutipong T. 2000. Interception, throughfall and stem flow of mixed deciduous with teak forest.

Crockford RH, Richardson DP. 2000. Partitioning of rainfall into throughfall, stemflow and interception: effect of forest type, ground cover and climate. Hydrology Process 14, 2903–2920.

Deguchi A, Hattori S, Park HT. 2006. The influence of seasonal changes in canopy structure on interception loss: Application of the revised Gash model. Journal hydrology, 318, 80–102.

Gasparoto EAG, Kelly CT, Emily TS, Roberta OAV. 2014. Throughfall in Different Forest Stands of  Iperó, São Paulo. Journal of Cerne,20(2), 303-310.http://dx.doi.org/10.1590/01047760.201420021260

Gomez KA, Gomez AA. 1984. Statistical Procedures for Agricultural Research (2nd ed.).John Wiley & Sons Inc., New York. USA.

Herwitz RS, Slye. 1992. Climate Needs and Problems in Widland Hidrology and Watersheds Research. Dept. of Forest, Canada.

Herwitz RS. 1985. Interception storage capacities of tropical rainforest canopy trees. Journal of Hydrology 77, 237-252.

Hidayat EB. 1992. Morfologi Tumbuhan Bandung , Jurusan Biologi ITB , Bandung.

Hutchion BA, Matt DR, McMillen RT, Gross LJ, Tajchman SJ, Norman JM. 1986. The architecture of a deciduous forest canopy in Eastern Tennessee, USA. Journal of Ecology 74, 635-646.

Kaimuddin. 1994. Kajian Pendugaan Intersepsi Hujan pada Tegakan Pinus merkusii, Agtahis loranthifolia dan Schima wallichii di Hutan Pendidikan Gunung Walat Sukabumi. Tesis.(unpublished). Magister Program Pascasarjana Institut Pertanian Bogor, Bogor.

Klassen W, Lankreijer HJM, Veen AWL. 1996. Rainfall interception near a forest edge. Journal of Hydrology185(1), 349-361.

Lu S, Tang K. 1995. Study on Rainfall Interception Characteristics of Natural Hardwood Forest in Central Taiwan; Bulletin of Taiwan Forestry Research Institute 10, 447–457.

Lin TC, Hsia YJ, King H. 1996. A Study on Rainfall Interception of a Natural  Hardwood Forest in Northeastern Taiwan. Journal Forestry 11, 393–400.

Link TE, Unsworth M, Marks D. 2004.  The Dynamics of Rainfall Interception by a Seasonal Temperate Rainforest. Journal of Agricultural Meteorology124, 171–191.

Muzylo A, Llorens P, Valente F, Keizer J, Domingo F, Gash J. 2009. A Review of Rainfall Interception Modelling. Journal Hydrology 370, 191–206.

Nedi S. 1997. Kajian Kualitas Air Sungai Siak di Kotamadya Pekanbaru. Tesis(unpublished). Sekolah Pascasarjana Institut Pertanian Bogor, Bogor.

Oliveira JJC, Dias HCT. 2005. Precipitação efetiva em fragmento secundário da Mata Atlântica. Revista Árvore, Journal of Viçosa 29, 6-15.

Ruslan M.1983. Intersepsi Curah Hujan pada Tegakan Tusam ( Pinus merkusii, Sungkai (Pinus canescens), dan Hutan Alam di DAS Riam Kanan, Kalsel. Tesis(unpublished). Fakultas Pascasarjana Universitas Pertanian Bogor.

Saberi O, dan Rosnani HM. 1999. Rainfall interception by lowland tropical rainforest in Air Hitam, Selangor, Malaysia. Dalam: Rahim, N.A. Water: Forestry and Land Use Perspectives. Technical Documents in Hydrology 70, 67-68.

Sadeghi SMM, Attarod P, Pypker TG, Dunkkerley D. 2014. Is Canopy Interception Increased In Semiarid Tree Plantation? Evidence From a Field Investigation In Tehran, Iran. Turkish Journal of Agriculture and Forestry 38, 792-806. http://dx.doi.org/10.3906/tar-1312-53.

Setiadi D.1998. Keterkaitan Profil Vegetasi sistim Agroforestry Kebun Campur dengan Lingkungannya. Disertasi(unpublished). Program Pasca Sarjana, Institut Pertanian Bogor.

Singh RP. 1987. Rainfall interception by Pinus wallichiana plantation in temperate region of Himachal Pradesh, India. Journal of Indian Forester 104, 559-566.

Supangat BS, Sudira P, Supriyono dan H,Poedjirahajoe E.2012. Studi Intersepsi Hujan pada Hutan Tanaman Eucalyptus pellita di Riau. Jurnal Agritech 32, 318-324.

Supranto J. 1986. Statistik Teori dan Aplikasi. Penerbit Erlangga, Jakarta.

Thomaz EL. 2005. Avaliação de Interceptação e Precipitação Interna em Capoeira e Floresta Secundária em Guarapuava, PR. Geografia, São Paulo 14, 47-60.

Waterloo MJ. 1994. Water and nutrient dynamics of Pinus caribaea plantation forests on former grassland soils in Viti levu, Fiji. PhD dissertation (unpublished). Vrije Universiteit van Amsterdam, Amsterdam, the Netherlands.

Yusop Z, Yen CS, Hui CJ. 2003. Throughfall, Stemflow and Interception Loss of Old Rubber Trees. Jurnal Kejuruteraan Awam 15, 24-33.