AI Article Synopsis
- The diversity of organic matter molecules complicates predictions on how the global carbon cycle will react to climate change, prompting the creation of an indicator to measure their environmental response.
- Researchers applied this indicator to study sediment dissolved organic matter in 480 aquatic microcosms across three mountain sites, finding that warmer climates intensified the thermal response of organic molecules.
- The study revealed that higher nutrient levels amplified this thermal response, with a notable increase in sensitivity linked to nitrogen loading, and the indicator also showed connections to greenhouse gas emissions.
Article Abstract
The diversity of intrinsic traits of different organic matter molecules makes it challenging to predict how they, and therefore the global carbon cycle, will respond to climate change. Here we develop an indicator of compositional-level environmental response for dissolved organic matter to quantify the aggregated response of individual molecules that positively and negatively associate with warming. We apply the indicator to assess the thermal response of sediment dissolved organic matter in 480 aquatic microcosms along nutrient gradients on three Eurasian mountainsides. Organic molecules consistently respond to temperature change within and across contrasting climate zones. At a compositional level, dissolved organic matter in warmer sites has a stronger thermal response and shows functional reorganization towards molecules with lower thermodynamic favorability for microbial decomposition. The thermal response is more sensitive to warming at higher nutrients, with increased sensitivity of up to 22% for each additional 1 mg L of nitrogen loading. The utility of the thermal response indicator is further confirmed by laboratory experiments and reveals its positive links to greenhouse gas emissions.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10794202 | PMC |
| http://dx.doi.org/10.1038/s41467-024-44813-2 | DOI Listing |
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