Abstract
The relationship between rain flow into the soil and forest structure was investigated in a dense deciduous Betula ermanii forest in northern Japan. The forest floor was covered with dwarf bamboo Sasa kurilensis. Observation was conducted from mid-July to late October in 1998. Leaf fall of Betula started in early September and ended in late October. Stemflow was proportional to rainfall and tree size [diameter at breast height (DBH)], and for the same rainfall, stemflow increased with leaf fall. On the contrary, throughfall decreased with leaf fall. Throughfall was intercepted also by Sasa in proportion to its leaf area. Multiple linear regression analysis revealed that stemflow and throughfall of Betula and Sasa were predictable as functions of rainfall and forest structural characteristics, such as DBH, tree density, and stand leaf mass. The rain interception by plants tended to decrease from summer to autumn, but the difference in the interception was about 2% between July (fully expanded leaves) and late October (lack of leaves). About 96 and 87% of rainfall reached the above- and below-Sasa layers, respectively. Thus, this study showed that understory Sasa is a major component of rain interception within the stand and that rain flow into the soil can be estimated by using rainfall and the forest structural parameters, such as DBH, tree density and stand leaf mass.
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References
Beier S, Hansen K, Gundersen P (1993) Spatial variability of throughfall fluxes in a spruce forest. Environ Pollut 81:257–267
Bréda N, Granier A, Barataud F, Moyne C (1995) Soil water dynamics in an oak stand. I. Soil moisture, water potentials and water uptake by roots. Plant Soil 172:17–27
Cienciala E, Kucera J, Ryan MG, Lindroth A (1998) Water flux in boreal forest during two hydrologically contrasting years; species specific regulation of canopy conductance and transpiration. Ann Sci For 55:47–61
Crockford RH, Richardson DP (2000) Partitioning of rainfall into throughfall, stemflow and interception: effect of forest type, ground cover and climate. Hydrol Process 14:2903–2920
Granier A, Bréda N (1996) Modelling canopy conductance and stand transpiration of an oak forest from sap flow measurements. Ann Sci For 53:537–546
Hattori S, Chikaarashi H (1988) Effect of thinning on canopy interception in a hinoki stand. J Jpn For Soc 70:529–533 (in Japanese)
Ikawa R (2007) Literature review of stemflow generation and chemical characteristics in Japanese forests. J Jpn Assoc Hydrol Sci 37:187–200
Ishii H, Kobayashi T, Uemura S, Takahashi K, Hanba Y, Sumida A, Hara T (2008) Removal of understory dwarf bamboo (Sasa kurilensis) induces changes in water-relation characteristics of overstory Betula ermanii trees. J For Res 13:101–109
Kallarackal J, Somen CK (1997) Water use by Eucalyptus tereticornis stands of differing density in southern India. Tree Physiol 17:195–203
Kawahara T, Suzuki T (1981) Studies on Sasa communities (VI) Biomass of Sasa kurilensis and Sasa paniculata communities. J Jpn For Soc 63:173–178 (in Japanese)
Kikuzawa K (1983) Leaf survival of woody plants in deciduous broad-leaved forests. I. Tall trees. Can J Bot 61:2133–2139
Kikuzawa K (1988) Intraspecific competition in a natural stand of Betula ermanii. Ann Bot 61:727–734
Kitamura K, Nakai Y, Sakamoto T, Terashima T, Shirai T (1996) Heat balance measurements on Sasa bamboo field. Transact. Jpn For Soc 107:323–326 (in Japanese)
Konno Y (1977) Ecology and distribution of Sasa. Shu Seibutsugaku Kenkyu 1:52–64 (in Japanese)
Marin CT, Bouten W, Sevink J (2000) Gross rainfall and its partitioning into throughfall, stemflow and evaporation of intercepted water in four forest ecosystems in western Amazonia. J Hydrol 237:40–57
Matsukata H, Ando M, Ogawa H (1990) Throughfall, stemflow and interception of rainwater in an evergreen broadleaved forest. Ecol Res 5:303–316
Miller BJ, Clinton PW, Buchan GD, Robson AB (1998) Transpiration rates and canopy conductance of Pinus radiata growing with different pasture understories in agroforestry systems. Tree Physiol 18:575–582
Murai H (1970) Studies on precipitation interception by forest vegetations. Bull Gov For Exp Sta 232:25–64 (in Japanese)
Murai H, Kumagai N (1989) Studies on effects of some treatments to forest so as to control stream flow in small mountain watershed (III)—influences on hydrological cycle in forest land and runoff and sediment discharge in stream. Bull Shizuoka Univ For 13:1–25 (in Japanese)
Oshima Y (1962) Ecological studies of Sasa communities V. Influence of light intensity, snow depth and temperature upon the development of Sasa kurilensis community. Bot Mag Tokyo 75:43–48
Park HT, Hattori S (2002) Applicability of stand structural characteristics to stemflow modeling. J For Res 7:91–98
Park HT, Hattori S, Kang HM (2000) Seasonal and inter-plot variations of stemflow, throughfall and interception loss in two deciduous broad-leaved forests. J Jpn Soc Hydrol Water Res 13:17–30
Potter CS (1992) Stemflow nutrient inputs to soil in a successional hardwood forest. Plant Soil 140:249–254
R Development Core Team (2009) R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. http://www.R-project.org
Sado Y, Kurita T (2004) Development of long-term forest management. Bull Yamaguchi Pref Exp For Center 17:14–18 (in Japanese)
Stogsdill WR Jr, Wittwer RF, Hennessey TC, Dougherty PM (1989) Relationship between throughfall and stand density in a Pinus taeda plantation. For Ecol Manage 29:105–113
Sumida A (1995) Three-dimensional structure of a mixed broad-leaved forest in Japan. Vegetation 119:67–80
Suzuki M, Kato H, Tani M, Fukushima Y (1979) Throughfall, stemflow and rainfall interception in Kiryu experimental catchment (I) throughfall and stemflow. J Jpn For Soc 61:202–210 (in Japanese)
Swank WT, Goebel NB, Helvey JD (1972) Interception loss in loblolly pine stands of the South Carolina Piedmont. J Soil Water Conserv 27:160–164
Takahashi K, Yoshida K, Suzuki M, Seino T, Tani T, Tashiro N, Ishii T, Sugata S, Fujito E, Naniwa A, Kudo G, Hiura T, Kohyama T (1999) Stand biomass, net production and canopy structure in a secondary deciduous broad-leaved forest, northern Japan. Res Bull Hokkaido Univ For 56:70–85
Takahashi K, Mitsuishi D, Uemura S, Suzuki J, Hara T (2003a) Stand structure and dynamics during a 16-year period in a sub-boreal conifer-hardwood mixed forest, northern Japan. For Ecol Manag 174:39–50
Takahashi K, Uemura S, Suzuki J, Hara T (2003b) Effects of understory dwarf bamboo on soil water and growth of overstory trees in a dense secondary Betula ermanii forest, northern Japan. Ecol Res 18:767–774
Takahashi K, Matsuki S, Uemura S, Hara T (2004) Variations in the maximum photosynthetic rate of Betula ermanii in relation to soil water potential. Veg Sci 21:103–108
Taniguchi K (1996) Role of Sasa communities on water budget in a watershed. MS. Thesis. Hokkaido University, Japan (in Japanese)
Whelan MJ, Anderson JM (1996) Modelling spatial patterns of throughfall and interception loss in a Norway spruce (Picea abies) plantation at the plot scale. J Hydrol 186:335–354
Yoda K, Kira T, Ogawa F, Hozumi K (1963) Self-thinning in overcrowded pure stands under cultivated and natural conditions (Intraspecific competition among higher plants. XI). J Biol Osaka City Univ 14:107–129
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We are grateful to D. Mitsuishi and the staff of Uryu Experimental Forest of Hokkaido University for their assistance.
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Takahashi, K., Uemura, S. & Hara, T. A forest-structure-based analysis of rain flow into soil in a dense deciduous Betula ermanii forest with understory dwarf bamboo. Landscape Ecol Eng 7, 101–108 (2011). https://doi.org/10.1007/s11355-010-0124-1
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DOI: https://doi.org/10.1007/s11355-010-0124-1