A new study published in Proceedings of the National Academy of Sciences (PNAS) solves a long-standing climate mystery: Why don't the records of oxygen isotopes (δ 18 O) in cave formations like stalagmites—known as speleothems—from central southern China reflect the well-known 100,000-year cycles of ice ages seen in other global climate records? These speleothem δ 18 O records have long been considered a key indicator of the strength of the Asian summer monsoon, so their failure to show these major climate shifts has puzzled scientists for decades.
To find an answer, researchers combined geological evidence with advanced climate model simulations. They discovered that the issue lies in how the δ 18 O signal in speleothems forms.
Meteorological data show that in southern China, less than half of the annual rainfall—and thus the dripwater that forms speleothems—comes from the summer monsoon season (June to August). The rest of the year's precipitation, from autumn, winter, and spring, contributes a larger share, and this nonsummer rainfall has significantly higher δ 18 O values. That means that speleothem δ 18 O reflects a mixture of rainfall from all seasons, not just the summer monsoon. Relying on it as a direct measure of summer monsoon strength is therefore misleading.
The key problem has been the lack of independent geological records that capture only the δ 18 O signal from summer rainfall—without the "seasonal mixing effect." To solve this, researchers from the Institute of Earth Environment at the Chinese Academy of Sciences, in collaboration with international partners, reconstructed a 400,000-year record of summer monsoon δ 18 O using a novel proxy: the δ 18 O of microcodium, microscopic carbonate particles formed when plant root cells calcify in Chinese loess deposits, mostly during the summer.
The new microcodium record and the traditional speleothem δ 18 O records both show 23,000-year variations. But only the microcodium record shows notably low δ 18 O values during peak interglacial periods, which correspond with strong summer monsoons. This clearly captures the 100,000-year glacial–interglacial cycles that are absent in the speleothem δ 18 O records from central southern China.
This shows that the speleothem δ 18 O records from central southern China reflect precipitation signals from multiple seasons, rather than exclusively summer precipitation. Acknowledging this seasonal "mixing effect" represents a significant shift in how speleothem δ 18 O records are interpreted.
Climate models support this explanation. They show that during peak interglacial periods with strong summer monsoons, when summer rainfall δ 18 O becomes more negative (indicating a stronger monsoon), the majority of the annual rain comes from nonsummer months—up to 60% or more. This diminishes the prominence of summer signals in speleothem δ 18 O records and explains the lack of significant negative δ 18 O excursions during peak interglacial periods, ultimately masking the 100,000-year cycles.
This finding not only resolves a long-standing mystery concerning the interpretation of East Asian speleothem δ 18 O records but also emphasizes the critical role of seasonality in understanding natural climate archives. It paves the way for reexamining the climatic significance of δ 18 O signals in speleothems—not just in East Asia but globally.
The research was jointly supported by the National Natural Science Foundation of China and Laoshan Laboratory, among other partners.
Proceedings of the National Academy of Sciences