长江流域资源与环境 >> 2012, Vol. 21 >> Issue (11): 1370-.

• 生态环境 • 上一篇    下一篇

不同植茶年龄茶园蒸散速率的日变化——以宜兴市为例

吕 文 |杨桂山 |万荣荣   

  1. (1.中国科学院南京地理与湖泊研究所湖泊与环境国家重点实验室|江苏 南京 210008;2.中国科学院研究生院|北京 100039)
  • 出版日期:2012-11-20

DAILY VARIATIONS OF EVAPOTRANSPIRATION RATES OF DIFFERENT AGES TEA PLANTATION IN YIXING CITY BASED ON STATIC CHAMBER/IGRA

LV Wen1,2|YANG Guishan1|WAN Rongrong1   

  1. (1.State Key Laboratory of Lake Science and Environment,Nanjing Institute of Geography&Limnology| Chinese Academy of Sciences|Nanjing 210008,China; 2.Graduate University of Chinese Academy of Sciences, Beijing 100039, China
  • Online:2012-11-20

摘要:

以宜兴市盛道茶场3、9和20 a 3个不同植茶年龄的茶园为研究对象,基于静态箱/红外气体分析仪法,辅以植被生态监测和土壤湿度监测,研究茶园清明采茶前蒸散速率日变化特征。结果发现:(1)3个不同植茶年龄的茶园日蒸散速率变化趋势一致,呈以12〖DK〗∶00~15〖DK〗∶00蒸散速率为峰值的单峰曲线;(2)虽然3 a茶园叶面积指数(LAI)最低,但最大平均日蒸散速率、一日内蒸散速率的极值、6〖DK〗∶00~18〖DK〗∶00最大总蒸散量、一日内不同时段的蒸散速率最大变化幅度均出现在3 a茶园;(3)茶园日蒸散速率与气温的日变化趋势相似,且两者存在极显著相关性(R2=081*〖KG-*2〗*),在湿润条件下与土壤含水率日变化相关性不明显,但两者呈相反的变化趋势

Abstract:

Applying Static Chamber/IRGA,this paper measured water vapor concentration of tea plantations of different growing years in Yixin City,on the west of Taihu Lake watershed,aimed to evaluate the effects of growing years on the diurnal variation of evapotranspiration.The results showed that diurnal variation of tea plantations evapotranspiration rate appeared in a single peak curve with the peak(273 mmol·m-2·s-1,236 mmol·m-2·s-1,209 mmol·m-2·s-1in the growing years order),increasing from 6〖DK〗∶00 and reaching a maximum value between 12〖DK〗∶00 and 15〖DK〗∶00,then decreasing rapidly.The three variations had the same trends,while their variation ranges during all time intervals were different from each other.The variation ranges decreased as the tea plantation growed,so the youngest one ’s(3 years old) amplitudes were the highest.Though the youngest’s LAI was the lowest(146<325<375 in the growing years order),it’s averge of diurnal evapotranspiration rates was the highest one(129 mmol·m-2·s-1>121 mmol·m-2·s-1>115 mmol·m-2·s-1 in the growing years order).Total evapotranspiration from 6〖DK〗∶00 to 18〖DK〗∶00 were also the highest(5052 g·m-2>4778 g·m-2>4502 g·m-2 in the growing years order),and the evapotranspiration rate maximum value during a day was in the order similar to the average ones,that the youngest’s was 049 mmol·m-2·s-1and 064 mmol·m-2·s-1 more than 9 years old one and 20 years old one respectively,as the 3 years old tea plantation’s lowest LAI brought most sunshine and surface turbulent flows which enhanced soil evaporation,canceled transpiration’s difference,and conclusively ,improved evapotanspiration.The diural evapotranspiration rate had the same trend with tempetature daily variation,in the morning,temperature was lowest(T〖TX-〗=383℃),evapotranspiration rate was lowest(ET〖TX-〗  rate=007 mmol·m-2·s-1) ,then the rate increased as the temperature rised.From 12〖DK〗∶00 to 15〖DK〗∶00,tempetature was highest(T〖TX-〗=3087℃),evapotranspiration rate came to the highest one (ET〖TX-〗 rate 232 mmol·m-2·s-1)during the day,then the rate declined rapidly as the temperature fell.And evapotranspiration rate of tea plantation was closely related to temperature(R2=081*〖KG-*2〗*).Three tea plantations’ temperatures increased 2700℃,2670℃ and 2740℃ in growing years order from 6〖DK〗∶00 to 12〖DK〗∶00,with little difference,while the amplitudes were 248 mmol·m-2·s-1,127 mmol·m-2·s-1,097 mmol·m-2·s-1 (in the growing years order)respectivily,with significant difference.From 15〖DK〗∶00 to 18〖DK〗∶00,amplitude reductions were 219 mmol·m-2·s-1,191 mmol·m-2·s-1 and 144 mmol·m-2·s-1 (in the growing years order),whose difference was much than the temperature drops.Soil moisture of the three tea plantations declined as evapotranspiration rates increased,both of them showed an opposite trend.In the morning,evapotranspiration rate was low,while soil moisture was relatively high,as the rate increased,soil moisture decreased gradually.When the rate reached the peak(from 12〖DK〗∶00 to 15〖DK〗∶00),all the soil moistures were in low level at noon.Then soil moisture recovered as the evapotranspiration rate declined.Though with a trend relationship between soil moisture and evapotranspration rate,there was no obvious correlation.The reason was probably that average daily soil moistures of the three tea plantations were 2441%,2546% and 2710% respectively,all of which were under wet condition and soil moisture had no significant effect on evapotranspiration.Soil moisture declined immediately as the evapotranspiration rate increased,the time when its low ebb appeared didn’t lag from the one when evapotranspiration reached to the peakas soil evaporation consumpted soil moisture by itself

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