静风下土壤水分胁迫的栓皮栎幼苗气候空间上限列线

doi:10.16843/j.sswc.2017.06.009

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摘要栓皮栎幼苗气候空间上限列线（SLCSUL）是反映高温胁迫温度指标的重要特征。研究选择在典型晴天，控制风速为0.2 m/s以下，测定并分析不同土壤干旱胁迫条件下，栓皮栎幼苗叶气温差随太阳辐射的变化规律，进而确定其气候空间上限列线（SLCSUL）。结果表明：1）太阳辐射对叶气温差起主导作用，晴天、静风条件下，上午叶气温差随太阳辐射强度的增强而增大，呈显著线性相关关系；2）叶气温差与太阳辐射线性相关的斜率均随土壤湿度的增加而降低，并呈显著线性相关；3）中午且严重干旱条件（土壤湿度为5%）下的叶温要比适宜土壤湿度下的叶温提高3 ℃，说明不同土壤湿度下，栓皮栎幼苗叶温随太阳辐射的变化而变化，与不同风速下叶温变化有相似的规律，不同土壤湿度也形成气候空间列线。该研究丰富了植物气候空间理论，并为农作物等其他植物多因子作用的热胁迫指标的确定提供指导。

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	王谦
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	张劲松
	寇渊博

关键词 ：栓皮栎, 叶气温差, 气候空间, 太阳辐射, 土壤容积含水量

Abstract：[Background] The Series Lines of Climate Space Up Limit (SLCSUL) of Quercus variabilis seedlings are important characteristics which may reflect more accurate temperature index of heat stress of high temperature. We had determined the serial lines of climate space of Q. variabilis seedlings in conditions of fully water supplied and different wind speeds. In this study we explored the leaf temperature of Q. variabilis seedlings changing with solar radiation, air temperature in condition of different soil moistures.[Methods] In the sunny weather conditions, controlling microclimate factor of wind speed under 0.2 m/s, and controlling different soil moisture conditions, the leaf and air temperature difference (LATD) of Q. variabilis seedlings were measured and the relation between LATD and the solar radiation were analyzed. Because leaf temperature index plus LATDs are leaf temperatures corresponding to different LATDs, the linear relation of LATD and the solar radiation was transformed into relation of leaf temperature and the solar radiation. According to the linear relation of leaf temperature and the solar radiation, leaf temperature increases with solar radiation increasing. This means solar radiation contracts climate space of Q. variabilis seedlings. Consulting D. M. Gates' climate space graphical method, overturn the regression line of leaf temperature and solar radiation, the SLCSUL of Q. variabilis seedlings were drawn.[Results] 1) The solar radiation was main factor of LATD, and LATD increased with solar radiation in clear and no wind weather. The relationship of LATD and solar radiation was remarkably linear relation. 2) The slope of linear relation of LATD and solar radiation decreased with soil moisture increasing. 3) In noon time, and in serious soil drought condition (soil moisture was 5%), the leaf temperature of Q. variabilis seedlings was 3℃ higher than in appropriate soil moisture condition.[Conculsions] We concluded that in different soil moisture conditions the leaf temperature of Q. variabilis seedlings increased with solar radiation increasing and the slope of LATD of different solar radiation decreased with soil moisture increasing. The LATD of different soil moisture changing with solar radiation was quite similar to the results of our former studies in different wind speed conditions, and it had the similar SLCSUL. Combining results of this paper with SLCSUL of different wind speed, the characteristics of climate space of Q. variabilis seedlings of 4 factors such as solar radiation, air temperature, soil moisture, and wind speed will be obtained. Therefore, the results of this paper may provide the basis for determining precise leaf temperature index of heat stress with multiple agro-meteorological factors. This paper enriches plant climate space theory and provides guidance for heat stress leaf temperature index determination of other plants, including crops, when multiple agro-meteorological factors are needed to be analyzed.

Key words： Quercus variabilis LATD climate space solar radiation soil moisture

收稿日期: 2016-12-26

PACS:

S157

基金资助:国家自然科学基金"基于气候空间上限列线的栓皮栎幼苗高温叠加干旱胁迫机制研究"（31370621）；国家自然科学基金"番茄叶片低温胁迫气象指标的气候空间列线研究"（31071321）

通讯作者: 陈景玲(1964-)女,本科,副教授。主要研究方向:农林业气象。Corresponding author.E-mail:chenjingling5@163.com E-mail: chenjingling5@163.com

作者简介: 王谦(1963-),男,博士研究生,教授。主要研究方向:农林业气象。E-mail:wangqianhau@163.com

引用本文:

王谦¹, 刘琳奇¹, 王佩舒¹, 曹静², 陈景玲¹, 张劲松³, 寇渊博¹. 静风下土壤水分胁迫的栓皮栎幼苗气候空间上限列线[J]. 中国水土保持科学, 2017, 15(6): 73-80.
WANG Qian, LIU Linqi, WANG Peishu, CAO Jing, CHEN Jingling, ZHANG Jingshong, KOU Yuanbo. Series lines of climate space up limit of Quercus variabilis seedlings in static wind and different soil water stress. SSWC, 2017, 15(6): 73-80.

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