Isotopic temporal and spatial variations of tropical rivers in Thailand reflect monsoon precipitation signals

Stable isotopic compositions (delta O-18 and d-excess) from 25 rivers in Thailand were analysed monthly during 2013-2015. Results indicated that monsoon precipitation fundamentally influences the river isotopes. The overland flow supplied from monsoon precipitation and human-altered flow regimes produces considerable isotopic variability. Spatial and temporal variations were observed among four principal geographical regions. The seasonality of monsoon precipitation in mountainous Thailand produced large variations in isotopic compositions because most rainfall occurred during the southwest monsoon, and dry conditions prevailed during the northeast monsoon. The northern and northeastern regions are mountainous, highland areas. Low delta O-18 values were found in these regions, likely because of altitude effects on precipitation. Conversely, monsoonal precipitation continually supplies rivers in southern Thailand all year round, producing higher and more consistent delta O-18 values than in the other regions. The Chao Phraya plain in the central region experienced enrichment of delta O-18 river runoff related to evaporation in irrigation systems. Larger catchment areas and longer residence times resulted in more pronounced evaporation effects, producing lower values of d-excess and local river water line slopes compared with precipitation. The isotopic differences between river waters and precipitation were utilized to determine river recharge elevations and water transit time. The methods presented here can be used to explore hydrological interactions in other tropical river basins.

Automated summary

Stable isotopic compositions of 25 rivers in Thailand were analyzed monthly from 2013 to 2015. The study found that monsoon precipitation significantly influences river isotopes, leading to spatial and temporal variations in isotopic compositions among different geographical regions. This research can be used to explore hydrological interactions in other tropical river basins.