日本地球惑星科学連合2014年大会

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インターナショナルセッション(口頭発表)

セッション記号 A (大気海洋・環境科学) » A-HW 水文・陸水・地下水学・水環境

[A-HW07_29AM1] Insight into change and evolution in hydrology

2014年4月29日(火) 09:00 〜 10:45 511 (5F)

コンビーナ:*谷 誠(京都大学大学院農学研究科地域環境科学専攻)、松四 雄騎(京都大学防災研究所 地盤災害研究部門 山地災害環境分野)、野口 正二(森林総合研究所)、中北 英一(京都大学防災研究所)、座長:野口 正二(森林総合研究所)、谷 誠(京都大学大学院農学研究科地域環境科学専攻)

09:30 〜 09:48

[AHW07-03] 乾燥熱帯域のチークプランテーションの水収支とその結果として起こる着葉期間

*田中 克典1 (1.独立行政法人海洋研究開発機構)

キーワード:着葉期間, 炭素獲得, 乾燥熱帯域, 土壌-植生-大気連続系, チークプランテーション, 水収支

A soil-plant-air continuum multilayer model was used to numerically simulate canopy net assimilation (An), evapotranspiration (ET), and soil moisture in a deciduous teak plantation in a dry tropical climate of northern Thailand to examine the influence of soil drought on An. The timings of leaf flush and the end of the canopy duration period (CDP) were also investigated from the perspective of the temporal positive carbon gain. Two numerical experiments with different seasonal patterns of leaf area index (LAI) were carried out using above-canopy hydrometeorological data as input data. The first experiment involved seasonally varying LAI estimated based on time-series of radiative transmittance through the canopy, and the second experiment applied an annually constant LAI. The first simulation captured the measured seasonal changes in soil surface moisture; the simulated transpiration agreed with seasonal changes in heat pulse velocity, corresponding to the water use of individual trees, and the simulated An became slightly negative. However, in the second simulation, An became negative in the dry season because the decline in stomatal conductance due to severe soil drought limited the assimilation, and the simultaneous increase in leaf temperature increased dark respiration. Thus, these experiments revealed that the leaflessness in the dry season is reasonable for carbon gain and emphasized the unfavorable soil water status for carbon gain in the dry season. Examining the duration of positive An (DPA) in the second simulation showed that the start of the longest DPA (LDPA) in a year approached the timing of leaf flush in the teak plantation after the spring equinox. On the other hand, the end appeared earlier than that of all CDPs. This result is consistent with the sap flow stopping earlier than the complete leaf fall, implying that the carbon assimilation period ends before the completion of defoliation. The model sensitivity analysis in the second simulation suggests that a smaller LAI and slower maximum rate of carboxylation likely extend the LDPA because soil water from the surface to rooting depth is maintained longer at levels adequate for carbon gain by decreased canopy transpiration. The experiments also suggest that lower soil hydraulic conductivity and deeper rooting depth can postpone the end of the LDPA by increasing soil water retention and the soil water capacity, respectively. These hypotheses will be verified based on observations.