Nighttime transpiration of Populus euphratica during different phenophases

Evidence exists of nighttime transpiration and its potential impact on plant/water relations for species in a diversity of ecosystems. However, relevant data related to typical desert riparian forest species remains limited Accordingly, we measured sap flow velocity of Populus euphratica using the heat ratio method between 2012 and2014. Nocturnal stem sap flow was separated into nighttime and stem refilling using the ‘‘forecasted refilling''method. Nighttime transpiration was observed for each phenophase. The highest value was during the full foliation period but lowest during leaf expansion and defoliation periods. The contribution of nighttime transpiration to daytime transpiration was an average of 15% but this was comparatively higher during the defoliation period. Relationships between nighttime transpiration, vapor pressure deficits, and air temperatures were more closely associated than with wind speed in all phenophases. Moreover, we found that nighttime transpiration linearly correlated to vapour pressure deficit during the first and the full foliation periods, but nighttime transpiration showed exponential correlations to air temperatures during the same phenophases. Additionally, environmental drivers of transpiration were significantly different between nighttime and daytime(P \ 0.05). Driving forces behind nighttime transpiration were characterized by many factors, and integrated impacts between these multiple environmental factors were complex. Future studies should focus on these integrated impacts on nighttime transpiration, and the physiological mechanisms of nighttime transpiration should be investigated, given that this could also influence its occurrence and magnitude during different phenophases.

Nighttime sap flow of Acacia mangium and its implications for nighttime transpiration and stem water storage

Aims Nighttime sap flow of trees may indicate transpiration and/or recharge of stem water storage at night.This paper deals with the water use of Acacia mangium at night in the hilly lands of subtropical South China.Our primary goal was to reveal and understand the nature of nighttime sap flow and its functional significance.Methods Granier’s thermal dissipation method was used to determine the nighttime sap flux of A.mangium.Gas exchange system was used to estimate nighttime leaf transpiration and stomatal conductance of studied trees.Important Findings Nighttimesap flowwas substantial and showed seasonal variation similar to the patterns of daytime sap flowin A.mangium.Mean nighttime sap flow was higher in the less precipitation year of 2004(1122.4 mm)than in the more precipitation year of 2005(1342.5 mm)since more daytime transpiration and low soil water availability in the relatively dry 2004 can be the cause of more nighttime sap flow.Although vapor pressure deficit and air temperature were significantly correlated with nighttime sap flow,they could only explain a small fraction of the variance in nighttime sap flow.The total accumulated water loss(E_(L))by transpiration of canopy leaves was only;2.6–8.5%of the total nighttime sap flow(E_(t))during the nights of July 17–18 and 18–19,2006.Therefore,it is likely that the nighttime sap flow was mainly used for refillingwater in the trunk.The stem diameter at breast height,basal area and sapwood area explained much more variance of nighttime water recharge than environmental factors and other tree form features,such as tree height,stem length below the branch,and canopy size.The contribution of nighttime water recharge to the total transpiration ranged from 14.7 to 30.3%depending on different DBH class and was considerably higher in the dry season compared to the wet season.

山西太岳山地区辽东栎林夏季热量平衡的研究

采用波文比能量平衡法对暖温带具有代表性的群落辽东栎纯林夏季热量平衡进行研究 ,测定热量平衡各分量。同时用TDM(ThermalDissipationMethod)法通过测定树干液流流量通量 ,得到蒸腾耗热通量 ,进而把蒸腾和蒸发从蒸发散中分开 。

北京山区元宝枫夜间液流活动特征及影响因素

树木夜间会维持部分气孔开放,从而能够在一定环境驱动因子的情况下进行夜间蒸腾。夜间液流作为储存水的重要来源,能够补充植物白天的水分亏缺,使其恢复水分储备,对植物生长发育有重要意义。采用TDP热探针法测定了位于八达岭林场的元宝枫树干液流密度,同步监测了主要环境因子,以深入揭示树木夜间蒸腾耗水规律和植被应对环境胁迫的调控机制,为山区植被建设、森林健康经营和挑选节水树种提供理论依据。结果表明:以0:00为界区分前半夜和后半夜,元宝枫夜间液流速率前半夜较后半夜活跃,且前半夜夜间累积液流量占夜间累积液流量的53.85%—64.10%,而后半夜夜间累积液流量占夜间累积液流量的35.9%—46.15%。5月的夜间累积液流量最大,平均夜间液流通量为5月>6月>8月>9月>7月。存在水分胁迫的条件下降雨之后夜间液流会增大,而当土壤水分条件较好,土壤水分不再是夜间液流的限制因子时,夜间液流通量并不高。不同树木形态的夜间液流通量有显著差异,在一定范围内,胸径树高冠幅越大的样木,夜间液流通量越大。用于夜间蒸腾的夜间液流通量与饱和水汽压差、温度、空气相对湿度、风速相关,其中夜间蒸腾存在于前半夜,表现为前半夜夜间液流通量与环境因子的相关性相较后半夜相关性较为显著,后半夜则以补水为主,补水量取决于土壤含水量和日蒸腾强度。存在干旱胁迫的条件下,夜间液流既用于夜间蒸腾,又有一部分用来补水;而土壤水分条件好时夜间液流则主要用于补水,此时夜间树干液流与环境因子相关性不高。元宝枫夜间液流通量的日蒸腾贡献率5、6月份大于7、8月份,即干季比湿季贡献率更高。夜间液流通量的日蒸腾贡献率与白天总蒸腾量相关性较高,并与累积太阳辐射成负相关。

半干旱区油松林分夜间液流变化特征及其影响因子

近年来,随着大气温度升高,树木蒸腾加剧,森林经营管理面临水资源短缺等一系列问题。夜间液流作为树干液流的重要组成部分,对准确估算林分耗水及水资源管理有着重要意义。于2019年生长季,以呼和浩特市树木园60年生油松为研究对象,采用热扩散法(TDP探针)测定树干液流,同步监测林外环境因子,以揭示半干旱区油松夜间液流调控机制。结果表明:1)生长季油松林分夜间液流呈现出明显的日、月变化。在日尺度上,油松林分夜间液流速率呈单一递减趋势,各月在00:00前均可以观测到明显夜间液流,且00:00前液流速率下降幅度更为明显;在月尺度上,油松林分夜间液流量5月最大,其次依次为9月>6月>8月>7月。2)在日尺度上,生长季油松林分夜间液流量与饱和水汽压差、土壤相对含水量和日间液流量呈显著正相关(P<0.05),与风速呈显著负相关(P>0.05)。生长季油松林分夜间液流平均贡献率为7%,不同影响因子对夜间液流贡献率的作用大小依次为日间液流量>饱和水汽压差>日间太阳总辐射。研究发现:生长季油松林分各月均存在明显的夜间液流,环境因子与油松林分夜间液流存在显著相关(P<0.05)。在林分尺度计算生长季各月液流量时,若不考虑夜间液流,月液流量将被低估3.0%~11.5%。

干旱绿洲农田无核白葡萄树蒸散发的分割研究

【目的】探究干旱绿洲区典型农田生态系统作物蒸腾蒸散特征及蒸腾占总蒸散的比值,为T/ET的研究提供数据支撑。【方法】联合运用树干液流(包裹式)、涡度相关法以及微气象观测系统于整个生长季(5—10月)对敦煌沙漠绿洲区无核白葡萄树(Vitis vinifera L.)的冠层蒸腾(Transpiration,T)和总蒸散(Evapotranspiration,ET)特征进行了连续测定;并分析了不同生态系统及不同观测模拟手段下蒸散发的分割结果。【结果】生长季中,冠层蒸腾量从0.20 mm/d上升到生长中期的8.13 mm/d,然后逐渐下降至末期落叶时到达极小值,日均蒸腾量为3.32 mm/d。总蒸散发量由0.44 mm/d增加到9.97 mm/d,然后逐渐下降至末期到达极小值,日均总蒸散量为4.91 mm/d。生长季冠层蒸腾量(T)占总蒸散量(ET)的值(T/ET)约为63.5%。【结论】生长季内,干旱绿洲区农田系统无核白葡萄树冠层蒸腾是总蒸散的主要水分通量。

九寨沟针阔混交林的夜间液流及其分配特征研究

利用Granier热扩散探针测定九寨沟针阔混交林3个主要树种2013年的树干液流密度,分析各树种夜间液流的季节变化特征及夜间茎干补水与夜间蒸腾的分配特征。结果表明,红桦(Betula albosinensis Burk.)和茶条槭(Acer ginnala Maxim.)的夜间液流占全天液流比例多为0~30%,油松(Pinus tabulaeformis Carr.)多为0~25%,但在某些特定条件下,夜间液流占比会超过40%;生长季各树种夜间液流占比均呈“U”型变化,生长季初期和末期较高,生长季中期较低;典型晴天内,各树种夜间液流密度均与饱和水汽压差呈极显著的线性关系(R2>0.95),表明夜间茎干补水和夜间蒸腾同时发生;红桦、茶条槭和油松的夜间茎干补水和蒸腾分别占夜间液流活动的80.7%和19.3%,81.4%和18.6%,63.9%和36.1%。

树木夜间液流组分划分方法对比——以毛白杨为例

夜间液流可通过叶片气孔流失,即夜间蒸腾,也可存储在茎干中,即茎干充水。从夜间液流中区分夜间蒸腾与夜间茎干充水是一个亟待解决的难题。预测充水法由于其便捷性被广泛应用,但其准确性备受质疑。为了系统分析现有的不同预测充水法在夜间液流组分划分中的准确性与适用性,该研究以毛白杨(Populus tomentosa)为实验材料,利用热扩散探针在高1.3 m处和7.0 m处进行液流测量,结合高度差法和预测充水法分别在茎干充水和夜间蒸腾上的准确性优势,分析对比4种传统预测充水法的估算效果。就4种预测充水法对不同高度液流进行分析得出的夜间蒸腾量而言,仅基于线性衰减模型的预测充水法(Line法)误差不显著,其他方法均存在较大偏差。采用4种预测充水法估算的茎干充水量与高度差法所得结果相比,仅基于蒸腾反推的预测充水法(Et法)的预测结果与之存在极显著差异,其余预测法差异均不显著,且Line法偏差最小。基于以上结果,该研究提出“液流高度差预测充水法”作为夜间液流组分划分新方法,可将夜间液流划分为3个组分,即茎干充水、冠层充水和夜间蒸腾。新方法通过高度差法提高对冠层以下茎干充水量估算的准确性,通过误差最小的Line法提高冠层充水组分和叶片蒸腾组分划分的准确性。新方法计算的夜间充水约为76.5%,较现有研究提高了19.8%-26.5%。划分出的夜间液流组分对环境因子的响应结果表明,空气水汽压亏缺(VPD)与浅层土壤含水率为夜间充水的主要影响因子,夜间蒸腾在夜间液流中的占比与VPD呈非线性负相关关系。

胡杨夜间液流通量及其影响因子研究

夜间液流在树木的整个生长过程中起着非常重要的作用,它不但与夜间蒸腾有关,而且有助于夜间自根系向上运输物质,为植物器官的夜间呼吸提供氧传递的机制。采用热比率技术,测量了荒漠河岸林自然生长条件下胡杨（Populus euphratica）的夜间液流通量大小、变化规律及影响因子。结果表明：① 4月胡杨夜间液流通量变化不大;5月和9月前半夜缓慢下降,后半夜缓慢上升,但变化幅度不大;6、7、8月均呈先下降后上升的趋势,且变化幅度较5月和9月大。②前半夜胡杨累积液流量约占整夜液流量的53%-62%,而后半夜仅占整夜累积液流量的38%-47%;后半夜液流通量显著低于前半夜;胡杨各月夜间累积液流量占整日累积液流量的比例依次为：4月（45.7%）〉5月（30.7%）〉8月（30.1%）〉9月（29.5%）〉6月（28.6%）〉7月（26.2%）,春季夜间累积液流量占整日累积液流量的比例大于夏季和秋季。③胡杨夜间液流通量受水汽压差、气温等影响,就4—9月来看,胡杨夜间液流通量与环境因子的相关系数依次为：水汽压差（0.63）〉气温（0.58）〉空气相对湿度（-0.335）〉土壤含水量（0.17）。水汽压差是影响夜间液流通量最关键的因子。

干旱区雨养多枝柽柳茎干液流动态及其对环境因子的响应

为探究干旱区雨养柽柳茎流速率与气象要素的关系,对多枝柽柳茎干液流速率及环境因子进行了同步监测。结果表明:1)不同天气条件下,柽柳液流速率的日变化进程明显不同;气象因子对柽柳液流影响依次为太阳辐射>水汽压差>气温>相对湿度>风速,回归模型能较好地解释不同月份柽柳液流速率变化。2)柽柳上、下午液流速率与太阳辐射变化呈非对称性,拟合结果在P<0.01的显著水平上R2均达0.930以上。3)夜间,柽柳维持着较稳定的低速液流,其量占全天液流量的3.92%~13.53%,且约有50%用于植物夜间蒸腾。