The d¹⁸O of stalagmite calcite (d¹⁸O_C) is an important source for terrestrial paleoclimate information. However, stalagmite d¹⁸O_C is controlled by two major factors: the temperature of calcite formation and the d¹⁸O of meteoric water (d¹⁸O_MW). The temperature and precipitation often covary spatially and temporally, and it is impossible to determine their relative importance by measuring only stalagmite d¹⁸O_C. A possible solution is estimating temperature by carbonate clumped isotope thermometry that is independent of the isotopic compositions of the environmental water from which stalagmite precipitates.
We analyzed stable oxygen isotope (d¹⁸O) and carbonate clumped isotopes (D₄₇) of two stalagmites from Hiroshima and Mie Prefectures (Kato et al., 2021; Kato et al., 2023 in press). The D₄₇ values of the two stalagmites exhibited time-series changes of terrestrial temperature from the latest Pleistocene to the mid-Holocene in Hiroshima (4.5-18.1 ka) and Mie (2.6-8.8 and 34.8-63.5 ka). In the period common to these two stalagmites (7.7-4.5 ka), they exhibit very similar patterns in D₄₇ temperature.
We reconstructed past meteoric d¹⁸O_MW by subtracting the temperature effect from d¹⁸O_C values of these stalagmites. The averaged d¹⁸O_MW values through the Holocene portions are less negative than those of the latest Pleistocene portions both in the study regions. Focusing on climatic changes at centennial-millennial timescale, d¹⁸O_MW values were more negative in colder periods, such as the Heinrich stadials and less negative in warmer periods such as the Hypsithermal. These relationships indicate the coevolution of terrestrial paleotemperature and paleoprecipitation.
Two major moisture sources to Japan are the Pacific Ocean and the Japan Sea, from which the East Asian summer monsoon (EASM) and East Asian winter monsoons (EAWM) bring moisture, respectively. Generally in the broad area of Japan except for south-west islands, summer rainfall has a d¹⁸O_MW value less negtive than winter rain/snowfall, and this pattern is also observed in our study regions. The intensities of EASM and EAWM are negatively correlated over multidecadal to millennial timescales, primarily as a result of internal variability in the Atlantic Meridional Overturning Circulation and its subsequent teleconnection to East Asia via land-sea thermal contrasts (Yan et al., 2020).
In our study regions, increased precipitation brought by EASM has likely increased the average d¹⁸O_MW in warmer climate stages, whereas increased precipitation brought by EAWM has decreased the averaged d¹⁸O_MW in colder climate stages. The temperature dependency of the fractionation from seawater to meteoric water is another factor determining the d¹⁸O_MW values.
The trend of more/less negative meteoric d¹⁸O_MW in warmer/colder climate stages is the opposite of that assumed in conventional stalagmite paleoclimate studies, which suggest that meteoric d¹⁸O_MW becomes more negative in warm-humid climates due to the "amount effect".

References
Kato H., Amekawa S., Hori M., Shen C.-C., Kuwahara Y., Senda R., Kano A. (2021) Influences of temperature and the meteoric water d¹⁸O value on a stalagmite record in the last deglacial to middle Holocene period from southwestern Japan. Quat. Sci. Rev. 253, 106746.
Kato H., Mori T., Amekawa S., Wu C.-C., Shen C.-C., Kano A. (2023 in press) Coevolutions of terrestrial temperature and monsoonal precipitation amounts from the latest Pleistocene to the mid-Holocene in Japan: Carbonate clumped isotope record of a stalagmite. Chem. Geol.
Yan M., Liu Z. Y., Ning L., Liu J. (2020) Holocene EASM-EAWM relationship across different timescales in CCSM3. Geophys. Res. Lett. 47, e2020GL088451.