Arid Central Asia (ACA). The contradictory understanding of Holocene climate change trends in ACA remains unresolved. This study compiled Holocene temperature and moisture changes from 23 lacustrine sediment sites in the ACA region based on quantitative proxies (reconstructed temperature and precipitation), physico-chemical proxies (carbon and oxygen isotopes of carbonates), and biological proxies ( n -alkanes). Holocene climate patterns characterized by early Holocene cold-dry, mid-Holocene cool-humid, and late Holocene warm-humid conditions in the ACA region. Multiple tipping points have been identified by different proxies during 10 8 and 6.5 3 cal ka BP, indicating inconsistencies among compilations of different proxy records. The long-term fluctuating warm-wetting trend in ACA is generally consistent with records from the westerly region, where Holocene climate changes are complex, in contrast to the relatively synchronized patterns in monsoonal Asia. Phase shifts of the North Atlantic Oscillation (NAO), driven by summer and winter insolation variations, caused latitudinal oscillations of westerly moisture transport. During mid-to-late Holocene, NAO negative phases shifted westerly moisture southward, dominating the warming-humidification trend in ACA region. However, the water resources in this region will exhibit complex spatiotemporal differentiation in the future, with wet regions becoming wetter and arid regions drier. This study demonstrates that multi-proxy compilation enhances understanding of regional climate change, but requires discerning environmental signals from different proxies. • Integrated climate proxies of 23 lacustrine sediment sites in arid Central Asia. • Temperature, precipitation, isotopes, and n -alkanes jointly reveal Holocene climate change. • Multiple tipping points of climate change were during 10 8 and 6.5 3 cal ka BP. • North Atlantic Oscillation phase affects Holocene westerlies climate changes. • Negative phase of North Atlantic Oscillation drives wetting of arid Central Asia.
Wang et al. (Tue,) studied this question.