Internal Model Variability of the Regional Coupled System Model GCOAST-AHOI

Ha Thi Minh Ho-Hagemann,Burkhardt Rockel,Joanna Staneva,Ronny Petrik,Stefan Hagemann,Frauke Feser,Corinna Schrum,Sebastian Grayek

doi:10.3390/atmos11030227

Ha Thi Minh Ho-Hagemann, Burkhardt Rockel + Show 6 more

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https://doi.org/10.3390/atmos11030227

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Journal: Atmosphere	Publication Date: Feb 26, 2020
Citations: 17	License type: CC BY 4.0

Affiliation: Helmholtz-Zentrum Hereon, Universität Hamburg

Abstract

Simulations of a Regional Climate Model (RCM) driven by identical lateral boundary conditions but initialized at different times exhibit the phenomenon of so-called internal model variability (or in short, Internal Variability—IV), which is defined as the inter-member spread between members in an ensemble of simulations. Our study investigates the effects of air-sea coupling on IV of the regional atmospheric model COSMO-CLM (CCLM) of the new regional coupled system model GCOAST-AHOI (Geesthacht Coupled cOAstal model SysTem: Atmosphere, Hydrology, Ocean and Sea Ice). We specifically address physical processes parameterized in CCLM, which may cause a large IV during an extreme event, and where this IV is affected by the air-sea coupling. Two six-member ensemble simulations were conducted with GCOAST-AHOI and the stand-alone CCLM (CCLM_ctr) for a period of 1 September–31 December 2013 over Europe. IV is expressed by spreads within the two sets of ensembles. Analyses focus on specific events during this period, especially on the storm Christian occurring from 27 to 29 October 2013 in northern Europe. Results show that simulations of CCLM_ctr vary largely amongst ensemble members during the storm. By analyzing two members of CCLM_ctr with opposite behaviors, we found that the large uncertainty in CCLM_ctr is caused by a combination of two factors (1) uncertainty in parameterization of cloud-radiation interaction in the atmospheric model. and (2) lack of an active two-way air-sea interaction. When CCLM is two-way coupled with the ocean model, the ensemble means of GCOAST-AHOI and CCLM_ctr are relatively similar, but the spread is reduced remarkably in GCOAST-AHOI, not only over the ocean where the coupling is done but also over land due to the land-sea interactions.

Highlights

Regional Climate Models (RCMs) are commonly used to downscale global climate information and to provide climate information on regional to local scales
We introduce a new AORCM, the GCOAST system, for climate simulations over the EURO-CORDEX domain with a focus on the North Sea and Baltic Sea regions
We analyze the Internal Variability (IV) of a sub-set of GCOAST, the AHOI coupled model, in a comparison with the stand-alone atmospheric model CCLM which is the atmospheric compartment of AHOI to find out if there is a potential benefit of air-sea coupling

Summary

Introduction

Regional Climate Models (RCMs) are commonly used to downscale global climate information and to provide climate information on regional to local scales. Simulations of RCMs are, associated with various sources of uncertainty. Understanding and potentially reducing these uncertainties is necessary to produce and deliver robust climate information, which, e.g., is of paramount importance for climate change impact studies [1]. A downscaled regional climate projection is affected by different sources of uncertainty that are compounded through the steps used to produce the projection. For each downscaling chain link, the uncertainties can be categorized into three main parts: Forcing, model response and natural internal variability (e.g., [2]).

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