Abstract. Much research is needed regarding the two long-term warming targets of the
2015 Paris Agreement, i.e., 1.5 and 2 ∘C above pre-industrial
levels, especially from a regional perspective. The East Asian summer
monsoon (EASM) intensity change and associated precipitation change under
both warming targets are explored in this study. The multimodel ensemble mean
projections by 19 CMIP5 models show small increases in EASM intensity and
general increases in summer precipitation at 1.5 and 2 ∘C warming,
but with large multimodel standard deviations. Thus, a novel multimodel
ensemble pattern regression (EPR) method is applied to give more reliable
projections based on the concept of emergent constraints, which is
effective at tightening the range of multimodel diversity and harmonize the
changes of different variables over the EASM region. Future changes projected
by using the EPR method suggest decreased precipitation over the Meiyu belt
and increased precipitation over the high latitudes of East Asia and Central
China, together with a considerable weakening of EASM intensity. Furthermore,
reduced precipitation appears over 30–40∘ N of East Asia in
June and over the Meiyu belt in July, with enhanced precipitation at their
north and south sides. These changes in early summer are attributed to a
southeastward retreat of the western North Pacific subtropical high (WNPSH) and a
southward shift of the East Asian subtropical jet (EASJ), which weaken the
moisture transport via southerly wind at low levels and alter vertical motions
over the EASM region. In August, precipitation would increase over the high
latitudes of East Asia with more moisture from the wetter area over the ocean
in the east and decrease over Japan with westward extension of WNPSH. These
monthly precipitation changes would finally contribute to a tripolar pattern
of EASM precipitation change at 1.5 and 2 ∘C warming. Corrected EASM
intensity exhibits a slight difference between 1.5 and 2 ∘C, but a
pronounced moisture increase during extra 0.5 ∘C leads to enhanced
EASM precipitation over large areas in East Asia at 2 ∘C warming.
A regional ocean–atmosphere coupled model developed for CORDEX East Asia: assessment of Asian summer monsoon simulation