Water vapor flux in tropical lowland rice

A field experiment was conducted at Indian Council of Agricultural Research-National Rice Research Institute, Cuttack, Odisha, India in the dry seasons of 2015 and 2016 to assess the water vapor flux (FH 2 O) and its relationship with other climatic variables. The FH 2 O and climatic variables were...

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Bibliographic Details
Published in:Environmental monitoring and assessment 2019-09, Vol.191 (9), p.550-550, Article 550
Main Authors: Chatterjee, Dibyendu, Nayak, Amaresh Kumar, Vijayakumar, S., Debnath, Manish, Chatterjee, Sumanta, Swain, Chinmaya Kumar, Bihari, Priyanka, Mohanty, S., Tripathi, Rahul, Shahid, Mohammad, Kumar, Anjani, Pathak, H.
Format: Article
Language:English
Subjects:
Agricultural research
Agriculture
Air temperature
Atmospheric Protection/Air Quality Control/Air Pollution
Carbon Cycle - physiology
Carbon dioxide
Carbon Dioxide - analysis
Carbon dioxide flux
Climate change
Correlation coefficient
Correlation coefficients
Covariance
Diurnal
Diurnal variations
Dry season
Earth and Environmental Science
Ecology
Ecosystem
Ecotoxicology
Eddy covariance
Environment
Environmental Management
Environmental monitoring
Environmental Monitoring - methods
Environmental science
Evaporation
Flowering
Fluctuations
Heat
Heat flux
Heat of vaporization
Heat transfer
India
Latent heat
Latent heat flux
Minimum temperatures
Monitoring/Environmental Analysis
Net radiation
Oryza - chemistry
Principal Component Analysis
Principal components analysis
Radiation
Radiation balance
Radiation flux
Relative humidity
Seasons
Short wave radiation
Soil
Soil - chemistry
Soil temperature
Soil water
Soils
Steam - analysis
Temperature
Tropical climate
Vapor pressure
Vaporization
Vaporization heat
Vapour pressure
Water - chemistry
Water temperature
Water vapor
Water vapor flux
Water vapour
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Summary:A field experiment was conducted at Indian Council of Agricultural Research-National Rice Research Institute, Cuttack, Odisha, India in the dry seasons of 2015 and 2016 to assess the water vapor flux (FH 2 O) and its relationship with other climatic variables. The FH 2 O and climatic variables were measured by an eddy covariance system and a micrometeorological observatory. Daily mean FH 2 O during the dry seasons of 2015 and 2016 were 0.009–0.092 g m −2 s −1 and 0.014–0.101 g m −2 s −1 , respectively. Seasonal average FH 2 O was 14.6% higher in 2016 than that in 2015. Diurnal variation for FH 2 O showed a bell-shaped curve with its peak at 13:30–14:00 Indian Standard Time (IST) in both the years. Carbon dioxide flux was found higher with rise in FH 2 O. This relationship was stronger at higher vapor pressure deficit (VPD) (20 ≤ VPD ≤ 40 and VPD > 40 hPa). The FH 2 O showed significant positive correlation with latent heat flux, net radiation flux, photosynthatically active radiation, air, water and soil temperatures, shortwave down and upwell radiations, maximum and minimum temperatures, evaporation, and relative humidity in both the years. Principal component analysis showed that FH 2 O was very close to latent heat flux in both the years (Pearson correlation coefficient close to 1). The two-dimensional observation map of the principal component F1 and F2 showed the observations taken during the vegetative stage and panicle initiation stage, and flowering stage and maturity stage were closer to each other. It can be concluded that the most important climatic variables controlling the FH 2 O were latent heat of vaporization, net radiation, air temperature, soil temperatures, and water temperature.
ISSN:0167-6369
1573-2959
DOI:10.1007/s10661-019-7709-4