Simulation of the West African monsoon onset using the HadGEM3-RA regional climate model

Ismaïla Diallo,Caroline L Bain,Richard Graham,Coumba Niang,Wilfran Moufouma-Okia,Amadou T Gaye,Mame D B Dieng

doi:10.1007/s00382-014-2219-0

Ismaïla Diallo, Caroline L Bain + Show 5 more

Open Access

https://doi.org/10.1007/s00382-014-2219-0

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Journal: Climate dynamics	Publication Date: Jul 5, 2014
Citations: 65	License type: CC BY 4.0

Affiliation: Cheikh Anta Diop University, Met Office

Abstract

The performance of the Hadley Centre Global Environmental Model version 3 regional climate model (HadGEM3-RA) in simulating the West African monsoon (WAM) is investigated. We focus on performance for monsoon onset timing and for rainfall totals over the June–July–August (JJA) season and on the model’s representation of the underlying dynamical processes. Experiments are driven by the ERA-Interim reanalysis and follow the CORDEX experimental protocol. Simulations with the HadGEM3 global model, which shares a common physical formulation with HadGEM3-RA, are used to gain insight into the causes of HadGEM3-RA simulation errors. It is found that HadGEM3-RA simulations of monsoon onset timing are realistic, with an error in mean onset date of two pentads. However, the model has a dry bias over the Sahel during JJA of 15–20 %. Analysis suggests that this is related to errors in the positioning of the Saharan heat low, which is too far south in HadGEM3-RA and associated with an insufficient northward reach of the south-westerly low-level monsoon flow and weaker moisture convergence over the Sahel. Despite these biases HadGEM3-RA’s representation of the general rainfall distribution during the WAM appears superior to that of ERA-Interim when using Global Precipitation Climatology Project or Tropical Rain Measurement Mission data as reference. This suggests that the associated dynamical features seen in HadGEM3-RA can complement the physical picture available from ERA-Interim. This approach is supported by the fact that the global HadGEM3 model generates realistic simulations of the WAM without the benefit of pseudo-observational forcing at the lateral boundaries; suggesting that the physical formulation shared with HadGEM3-RA, is able to represent the driving processes. HadGEM3-RA simulations confirm previous findings that the main rainfall peak near 10°N during June–August is maintained by a region of mid-tropospheric ascent located, latitudinally, between the cores of the African Easterly Jet and Tropical Easterly Jet that intensifies around the time of onset. This region of ascent is weaker and located further south near 5°N in the driving ERA-Interim reanalysis, for reasons that may be related to the coarser resolution or the physics of the underlying model, and this is consistent with a less realistic latitudinal rainfall profile than found in the HadGEM3-RA simulations.

Highlights

The West African economy and its food supply depend strongly on local agriculture, which is in turn highly dependent on climate, on seasonal rainfall
Improving the understanding and predictability of the West African monsoon (WAM) is of high importance for the Sudano-Sahelian countries, whose economies are mainly based on rain-fed agriculture and vulnerable to climate variability
In this study we have evaluated simulations generated by the Hadley Centre Global Environmental Model version 3 (HadGEM3)-RA regional climate model (RCM) and used these simulations, together with ERA-Interim reanalysis data to investigate the dynamics behind the characteristic rainfall evolution, including the discontinuous northward jump of the rainband in late June that signals the onset of the rains in the Sahel region

Summary

Introduction

The West African economy and its food supply depend strongly on local agriculture, which is in turn highly dependent on climate, on seasonal rainfall. Rainfall maxima occur during the peak of the West African monsoon (WAM) in June–July–August (JJA) and are associated with the meridional displacement of the intertropical convergence zone (ITCZ). There is an abrupt shift of rainfall maxima northward to hold another quasi-stationary position near 11°N in JJA. This abrupt latitudinal shift corresponds to the monsoon ‘‘onset’’ and contrasts to the smooth retreat of the ITCZ southward in October– November. Reliable projections of potential changes to the WAM and its onset characteristics are important to inform climate change adaptation in most socio-economic sectors in the region. This paper is concerned with assessing the quality of the HadGEM3-RA simulations of the monsoon; a faithful simulation being evidence that the model has a sound physical basis for use in future projection

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