Performance of the Taiwan Earth System Model in Simulating Climate
Variability Compared with Observations and CMIP6 Model Simulations
Abstract
This study evaluated the performance of the Taiwan Earth System Model
version 1 (TaiESM1) in simulating the observed climate variability in
the historical simulation of the Coupled Model Intercomparison phase 6
(CMIP6). TaiESM1 was developed on the basis of the Community Earth
System Model version 1.2.2, with the inclusion of several new physical
schemes and improvements in the atmosphere model. The new additions
include an improved triggering function in the cumulus convection
scheme, a revised distribution-based formula in the cloud fraction
scheme, a new aerosol scheme, and a unique scheme for three-dimensional
surface absorption of shortwave radiation that accounts for the
influence of complex terrains. In contrast to the majority of model
evaluation processes, which focus mainly on the climatological mean,
this evaluation focuses on climate variability parameters, including the
diurnal rainfall cycle, precipitation extremes, synoptic eddy activity,
intraseasonal fluctuation, monsoon evolution, and interannual and
multidecadal atmospheric and oceanic teleconnection patterns. A series
of intercomparisons between the simulations of TaiESM1 and CMIP6 models
and observations indicate that TaiESM1, a participating model in CMIP6,
can realistically simulate the observed climate variability at various
time scales and performs better than the other CMIP6 models in terms of
many key climate features.