The Asian Summer Monsoon (ASM) and its variations affect the living of billions of people in the Asia region. Understanding ASM variability and its effect are crucial for governments to prepare for climate change. For nearly twenty decades, speleothems have been used as one of a vital nature archives to reconstruct paleo-hydroclimate variation from orbital to centennial timescale levels. The climatic interpretation based on stalagmite stable isotope proxies, particularly the oxygen isotope ratio (δ18O), can provide trustworthy, high-resolution terrestrial records in pair with ice core records on monthly-to-decadal resolutions. In my dissertation, I used speleothems from northern Vietnam to reconstruct the variability of the ASM during 32-23 thousand years (ka, relative to AD 1950) and its behavior which is essential to Asia's economic and cultural development. Three important key findings have been reached in this dissertation. Firstly, a decadal-resolved stalagmite oxygen isotope record retrieved from a cave in Northern Vietnam, corresponding to three millennial Dansgaard–Oeschoger (D-O) events registered in the Greenland ice cores. The oxygen isotope record suggests that the monsoon has responded synchronously across the Asia region to D–O events. Secondly, I obtained a high-resolved speleothem δ18O record, covering the entire Heinrich Event (HE) 3. The δ18O result clearly displays a drying trend during HE-3, which started from 30.8 ka, stayed at a maximum of over 100 years at around 30.3 to 30.2 ka, and fully recovered at 29.6 ka. The onset and recovery periods are characterized by gradually stepping change, depicting a V shape on a millennium scale. It implies the moisture source of Northern Vietnam site, the Indian Summer Monsoon, underwent an intensity decrease during HE-3. The gradual V-shape record also suggests that this monsoonal decrease was probably provoked by the thermal behavior change of the source ocean. It is consistent with the hypothesis that the Southern Ocean was under relatively warm conditions during HE due to shutting down the Atlantic Meridional Ocean Circulation (AMOC), which drives the ITCZ to migrate to the south. Third, relative to the δ18O record, the δ13C excursion commenced 100 years later but ended 300 years earlier. The timing and spatial location of the carbon isotope excursion indicate a temporary decline in C3 plant coverage and expansion of C4 plants at the study site during HE-3. The δ13C record thus documents the resilience of plant communities and associated ecosystems in response to HE-3. Additionally, the author shows evidence of the solar cycle in late Pleistocene speleothem record from Thuong Thien (TT) Cave, Vietnam. The record demonstrated the existence of centennial-scale events, which possibly correlate to the Sues cycle of solar activity, suggesting an essential role of solar activity in controlling ASM. These findings in this dissertation contribute to our understanding of ASM variability and demonstrate the critical plays of the tropical region in the climate system, and therefore, help forecast hydro-climate change of the area in the future.