Seasonal variation of temporal patterns of water flux in a cashew orchard under sub-humid tropical conditions.

Oguntunde P. G.; Ajayi A. E.; Friesen J.; Giesen N. van de; Vlek P. L. G.

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Seasonal variation of temporal patterns of water flux in a cashew orchard under sub-humid tropical conditions.

机译：亚湿热带条件下腰果园水通量的时空分布特征的季节性变化。

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There is a growing interest in the understanding of the dynamics of sap flow and the transpiration process in plants. In this study, Xylem sap flux was monitored in a 4-year-old cashew (Anacardium occidentale) orchard for eight months (2-4 weeks per month), covering both wet and dry seasons of 2002 at Ejura in Ghana. Sap flux (F_d) was related diurnally with vapor pressure deficit (D_e), incoming solar radiation (R_s), and estimated evaporative demand (E_o) on a monthly and a seasonal basis. Cross-correlation analysis was used to estimate time lag ( tau ) between diurnal pattern of F_d and R_s, D_e or E_o. The maximum correlation coefficient (r_max) from cross-correlation of F_d with R_s (range=0.85-0.93) was often slightly higher than r_max of F_d and D_e (range=0.83-0.92), indicating that the diurnal F_d was more dependent on R_s than D_e, for most part of the year. Generally, tau of F_d with R_s ranged from 0-60 min, 0-30 min with E_o, and led D_e from 0-180 min during the year. Student t-test showed that average diurnal F_d was not statistically different, from month to month, all year round, suggesting that trees were able to source for required water even during February and March, which are the peak dry months in West Africa. Regressions between F_d and D_e or R_s showed that D_e exerted more control on tree water use during the wet (June, July, October) than dry (January, February, March) or transition (November, December) periods. The good relation of F_d with the climatic parameter was exploited to calibrate an approximation function to predict seasonal water use to a very high degree of accuracy. A simple mono-climatic model, combining the parabolic response of Fd to R_s and the linear response to D_e, was highly successful (F=9118.5, P<0.0001, r2=0.82, n=3984) in predicting sap flux in the orchard. This result suggested that sap flow data might be used to estimate stand transpiration conveniently at about hourly time steps to avoid the usual time-lag problem associated with the use of sap flow data for transpiration estimates.Digital Object Identifier http://dx.doi.org/10.1080/15427528.2011.591482

机译：人们对植物汁液流动和蒸腾过程的动态认识越来越浓厚。在这项研究中，在一个4岁的腰果果园中监测了木质部的汁液通量，历时8个月（每月2-4周），涵盖2002年的湿季和干季。加纳的埃朱拉。汁液通量（F _{d ）与蒸气压亏缺（D _{e ），入射太阳辐射（R _{s ）和估计的蒸发量呈昼夜关系。每月和季节性需求（E _{o ）。使用互相关分析来估计F _{d 与R _{s ，D _{e 或E o 。 F _{d 与R _{s 的互相关的最大相关系数（r _{max ）通常稍高一些（范围= 0.85-0.93）比F _{d 和D _{e 的r _{max （范围= 0.83-0.92），表明日F _{d s 而不是D _{e 。通常，带有R _{s 的F _{d 的tau范围是0-60分钟，带有E _{o 的0-30分钟，并且导致D 。学生t检验显示，全年的月平均F _{d 在统计上没有差异，这表明树木即使在2月和3月也能够获得所需的水。西非干燥月份的高峰期。 F _{d 和D _{e 或R _{s 之间的回归表明，D _{e 对树水的使用有更大的控制作用。潮湿（6月，7月，10月）比干燥（1月，2月，3月）或过渡（11月，12月）时期要多。利用F _{d 与气候参数的良好关系来校准近似函数，以非常高的准确性预测季节用水。结合Fd对R _{s 的抛物线响应和对D _{e 的线性响应的简单单气候模型非常成功（F = 9118.5，P <0.0001， r 2 = 0.82，n = 3984）预测果园的汁液通量。这个结果表明，树液流量数据可以在大约每小时的时间步长上方便地估算林分蒸腾量，从而避免了与使用树液流量数据进行蒸腾量估算相关的常见时滞问题。数字对象标识符http：//dx.doi .org / 10.1080 / 15427528.2011.591482}}}}}}}}}}}}}}}}}}}}}}}}}}

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来源
《Journal of Crop Improvement》 |2011年第5期|共17页
作者
Oguntunde P. G.; Ajayi A. E.; Friesen J.; Giesen N. van de; Vlek P. L. G.;
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正文语种 eng
中图分类农作物;
关键词
Anacardium occidentale; xylem sap ?ux; time lag; seasonal patterns; vapor pressure de?cit; incoming solar radiation; evaporative demand;

机译：西洋参无心果;木质部汁液流失;时滞;季节型式;蒸气压下降;太阳辐射的传入;蒸发需求;

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Seasonal variation of temporal patterns of water flux in a cashew orchard under sub-humid tropical conditions.

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