Tibet’s thawing lakes accelerate greenhouse gas release

Lakes on the Tibetan Plateau are undergoing a dramatic transformation; once stable carbon sinks, they are rapidly becoming significant sources of greenhouse gases due to climate warming— the main takeaway from a new review published in Fundamental Research.

The study, which analyzed nearly 400 scientific papers, reveals that rising temperatures are accelerating permafrost thaw and glacier retreat. This process feeds the expansion of "thermokarst" lakes—new water bodies formed by melting permafrost. These lakes are critical hotspots, as they release ancient, long-frozen carbon as both carbon dioxide (CO2) and, more critically, as methane (CH4), a greenhouse gas 28 times more potent than CO2.

"Our review shows that the role of these plateau lakes is not uniform," says Dr. Yang Liu, the corresponding author of the study. "They have differentiated into distinct types, ranging from significant carbon sinks to powerful carbon sources. This finding underscores the urgent need to move beyond simple assessments and adopt typology-based management strategies."

The research, which provides critical scientific support for regional green development and global carbon neutrality strategies, turning what were once "neglected carbon sources" into "manageable carbon sinks, highlights the central role of microorganisms, which act as the "core engine" driving these emissions. Microbes decompose organic matter and cycle key nutrients like carbon, nitrogen, and sulfur. Notably, while warming extends the growing season for algae (which absorb CO2), it simultaneously supercharges microbial decomposition. This dual effect risks flipping the entire system from a net carbon absorber to a net emitter, creating a dangerous positive feedback loop that exacerbates global warming.

The authors call for an integrated, multi-factor model that incorporates microbial functional genes, nutrient coupling, and climate drivers. "Such a model would allow for "lake-type zoning" management—protecting lakes that remain carbon sinks while mitigating emissions from thermokarst and other high-emitting lakes," adds Liu.

###

Contact the author: Yang Liu, Xizang University, ly@utibet.edu.cn

The publisher KeAi was established by Elsevier and China Science Publishing & Media Ltd to unfold quality research globally. In 2013, our focus shifted to open access publishing. We now proudly publish more than 200 world-class, open access, English language journals, spanning all scientific disciplines. Many of these are titles we publish in partnership with prestigious societies and academic institutions, such as the National Natural Science Foundation of China (NSFC).