starvation and biotic agents [34].

starvation and biotic agents [34]. Due to the tempo-spatial
mismatch between field observations and laboratory simulations,
it is difficult to determine which mechanism is the main driving
factor [13]. Before understanding the mechanisms underlying
climate change and forest, the quantitative knowledge about the
physiological thresholds of individual tree death under chronic or
acute water stress should be required [1]. Notably, the relationship
between the threshold for tree mortality and drought-induced
water stress, which may also underlie the effects of biotic agents
such as bark beetles [49], remains uncertain.
More severe drought, as produced by climate change, has the
potential to trigger or aggravate widespread tree die-off
[57,34,13]. The consequences of drought-induced forest die-off
should be manifold for ecosystems, and the climate system
[65].Widespread global and regional scale die-off events could
change forest structure and composition, consequently impacting
the stability of land-surface interactions such as carbon sequestration
and possibly causing feedback for atmospheric CO2 and climate
[57,34,4]. Multi-year drought has been shown to initiate
prolonged growth decreases that increase a tree’s long-term risk
of death [6] for two reasons: (1) Tree death occurs generally
several years or even several decades after the drought [6]. (2)
Reductions in tree density following mortality events failed to
buffer sites against additional mortality during subsequent
droughts, so the ‘release effect’ of tree mortality did not increase
the ability of the surviving trees to endure the next severe drought
[36]. Furthermore, extended periods of warm, dry conditions could
weaken the ability of trees to withstand insect attacks [1,22],
which may lead to more severe tree mortality. More researches
are still needed on micro-climatic, hydrological, and biogeochemical
consequences of and feedbacks to mortality [65].