Behavior of temperature-based water stress indicators in BIOTIC-controlled irrigation

A subsurface drip irrigation study with cotton used canopy temperature to determine signals for irrigation control during 2002-2004. Timing of irrigation applications was controlled by the biologically identified optimal temperature interactive console (BIOTIC) protocol, which used stress time (ST)...

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Bibliographic Details
Published in:Irrigation science 2006-05, Vol.24 (4), p.223-232
Main Authors: Wanjura, D.F, Upchurch, D.R, Mahan, J.R
Format: Article
Language:English
Subjects:
Air temperature
biologically identified optimal temperature interactive console
Canopies
canopy
controllers
Cotton
Crop production
Crop science
crop yield
daily average canopy temperature
Drip irrigation
Gossypium hirsutum
Irrigation
irrigation requirement
irrigation scheduling
irrigation systems
microirrigation
relative crop water stress index
stress time
subsurface irrigation
Temperature
Water stress
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Summary:A subsurface drip irrigation study with cotton used canopy temperature to determine signals for irrigation control during 2002-2004. Timing of irrigation applications was controlled by the biologically identified optimal temperature interactive console (BIOTIC) protocol, which used stress time (ST) and a crop-specific optimum temperature to indicate water stress. ST was the cumulative daily time quantity when cotton canopy temperature exceeded 28°C. STs between 5.5 and 8.5 h in 1 h increments were irrigation signal criteria, which produced different irrigation regimes. This investigation examined the association among ST, daily average canopy temperature (T c), canopy and air temperature difference (T c-T a), and the relative crop water stress index (RCWSI) including their relationship with lint yield. Number of irrigation signals decreased linearly with ST at the rate of -10.2 and -8.7 irrigations per 1 h increase of ST in 2003 and 2004. There were significant curvilinear relationships between ST and the average daily stress on days with irrigation signals and for days without irrigation signals across years. The percentage of positive daily (T(c)-T(a)) values increased with ST level. ST and T c were positively related in all irrigation signal treatments with 5.5 and 6.5 h being significant in 2003 and 2004. Yield declined at the rate of 343 kg lint/ha for each 1 h increase of ST for days with irrigation signals. ST, mathematically the most simple of the canopy temperature-based parameters, provided the most consistent estimate of crop water stress and correlation with lint yield. The power of ST to characterize water stress effects on crop productivity evolves from being an integrated value of time while canopy temperature exceeds a physiologically based threshold value.
ISSN:0342-7188
1432-1319
DOI:10.1007/s00271-005-0021-9