徐珊等:Diurnal Response of Sun-Induced Fluorescence and PRI to Water Stress in Maize Using a Near-Surface Remote Sensing Platform
被阅读 399 次
2018-12-06
Diurnal Response of Sun-Induced Fluorescence and PRI to Water Stress in Maize Using a Near-Surface Remote Sensing Platform
作者:Xu, S (Xu, Shan)[ 1,2 ] ; Liu, ZG (Liu, Zhigang)[ 1,2 ] ; Zhao, L (Zhao, Liang)[ 1,2 ] ; Zhao, HR (Zhao, Huarong)[ 3 ] ; Ren, SX (Ren, Sanxue)[ 3 ]
REMOTE SENSING
卷: 10  期: 10
文献号: 1510
DOI: 10.3390/rs10101510
出版年: OCT 2018
 
摘要
Sun-induced Fluorescence (SIF) and Photochemical Reflectance Index (PRI) data were collected in the field over maize to study their diurnal responses to different water stresses at the canopy scale. An automated field spectroscopy system was used to obtain continuous and long-term measurements of maize canopy in four field plots with different irrigation treatments. This system collects visible to near-infrared spectra with a spectrometer, which provides a sub-nanometer spectral resolution in the spectral range of 480850 nm. The red SIF (F-R) and far red SIF (F-FR) data were retrieved by Spectral Fitting Methods (SFM) in the -A band and -B band, respectively. In addition to PRI, values were derived from PRI by subtracting an early morning PRI value. Photosynthetic active radiation (PAR) data, the canopy fraction of absorbed PAR (fPAR), and the air/canopy temperature and photosystem II operating efficiency (YII) at the leaf scale were collected concurrently. In this paper, the diurnal dynamics of each parameter before and after watering at the jointing stage were compared. The results showed that (i) both F-R and F-FR decreased under water stress, but F-R always peaked at noon, and the peak of F-FR advanced with the increase in stress. Leaf folding and the increase in Non-photochemical Quenching (NPQ) are the main reasons for this trend. Leaf YII gradually decreased from 8:00 to 14:00 and then recovered. In drought, leaf YII was smaller and decreased more rapidly. Therefore, the fluorescence yield at both the leaf and canopy scale responded to water stress. (ii) As good indicators of changes in NPQ, diurnal PRI and data also showed specific decreases due to water stress. can eliminate the impact of canopy structure. Under water stress, decreased rapidly from 8:00 to 13:00, and the maximum range of this decrease was approximately 0.05. After 13:00, their values started to increase but could not recover to their morning level. (iii) Higher canopy-air temperature differences indicate that stomatal closure leads to an increase in leaf temperature, which maintains a higher state in the afternoon. In summary, to cope with water stress, both leaf folding and changes in physiology are activated. To monitor drought, SIF performs best around midday, and PRI is better after noon.
 
通讯作者地址: Liu, ZG (通讯作者)
State Key Lab Remote Sensing Sci, Beijing 100875, Peoples R China.
通讯作者地址: Liu, ZG (通讯作者)
Beijing Normal Univ, Inst Remote Sensing Sci & Engn, Fac Geog Sci, Beijing Engn Res Ctr Global Land Remote Sensing P, Beijing 100875, Peoples R China.
地址:
[ 1 ] State Key Lab Remote Sensing Sci, Beijing 100875, Peoples R China
[ 2 ] Beijing Normal Univ, Inst Remote Sensing Sci & Engn, Fac Geog Sci, Beijing Engn Res Ctr Global Land Remote Sensing P, Beijing 100875, Peoples R China
[ 3 ] Chinese Acad Meteorol Sci, Beijing 100081, Peoples R China