Research Highlights
Unraveling the Drought Dilemma: Can Reservoirs Be a Carbon Source?
[POSTECH Professor Jonghun Kam’s team successfully delve into the spatiotemporal patterns of water volume and total organic carbon concentration of agricultural reservoirs]
Professor Jonghun Kam and Kwang-Hun Lee, a PhD student, from the Division of Environmental Science and Engineering at Pohang University of Science and Technology (POSTECH) analyzed water quantity and quality data from domestic agricultural reservoirs to shed light on the hydrological impacts of a severe drought on degrading the water quality. Their research findings were recently published in “Water Research”.
The recent climate crisis has resulted in more frequent extreme weather events, such as droughts and floods. Although models have outlined the anticipated effects of these extreme events on the global water cycle and carbon cycle, efforts to quantitatively comprehend them using observational data have been limited by the limited available big data on water quantity and quality
During spring, the onset of rice planting necessitates ample water in rice paddies and fields in South Korea. Since precipitation is not consistent from year to year and from season to season, over 3,000 agricultural reservoirs across the country have employed for water resource management. Water level data from agricultural reservoirs has been monitored the amount of water available during the crop planting season with additional collection of seasonal water quality data from the reservoirs since 2020. This national-level dataset from the reservoirs offers a unique opportunity to investigate coupled dynamics of the water and carbon cycle.
In their study, researchers utilized rotated principal component analysis*1 to extract key major modes of the extensive datasets of water levels and water quality that encompasses information on water volumes and total organic carbon (TOC) concentrations from over 2,200 agricultural reservoirs in Korea spanning from 2020 to 2022. During the study period, reservoir volumes ranged from 289 to 360 metric tons (106t), TOC concentrations varied between 3.54 and 4.60 mg/L, and TOC loads ranged from 1,165 to 1,492 tons.
The first major mode of the rotated principal component analysis unveiled a notable trend: as water temperatures rose and reservoir levels dwindled due to drought in the southern region of the Korean Peninsula in 2022, there was a corresponding increase in TOC concentrations. In the second major mode, the researchers observed a significant correlation between fluctuations in reservoir levels in the central area and shifts in TOC concentrations. Moreover, the research found that elevated TOC concentrations were observed in a region where a larger areal fraction of rice paddy fields surrounding agricultural reservoirs. These findings underscore the potential shift of the role of agricultural reservoirs from carbon storage to carbon source that emits carbon into the atmosphere during the period of a severe drought.
Professor Jonghun Kam stated, “By leveraging water big data and advanced statistical methodologies, we’ve quantitatively demonstrated alterations in the water and carbon cycles triggered by extreme drought.” He emphasized, “This underscores the pressing need to develop integrative environmental and water policies to prioritize both quantity and quality, especially as we transition into a carbon-neutral era.”
The research was conducted with the support from the Ocean, Land, and Atmosphere Carbon Cycle System Research Program of the National Research Foundation of Korea.
DOI: https://doi.org/10.1016/j.watres.2024.121610
1. Rotated Principal Component Analysis
An advanced statistical technique that extracts data from high-dimensional data and condenses it into a few principal components, representing crucial information, and subsequently rotates these components to refine their interpretation