Coupled Model Data Assimilation:

1. Coupled Model Data Assimilation: Building an idealised coupled system Polly Smith, Amos Lawless, Alison Fowler* School of Mathematical and Physical Sciences, University of Reading, UK * funded by NERC

2. Outline • Objectives • Tasks & progress • Issues • Next steps/ targets for next 6 months

3. Objective To use an idealised system to gain a greater theoretical understanding of the coupled atmosphere-ocean data assimilation problem: • explore different approaches to coupled 4D-Var data assimilation using a single-column, coupled atmosphere-ocean model • help guide the design/ implementation of coupled DA methods within full 3D operational scale systems • strong-constraint incremental 4D-Var

4. Building the idealised system Task 1: develop an idealised, single-column, coupled atmosphere-ocean model with a strong-constraint incremental 4D-Var assimilation scheme. For this we need a model that • is simple and quick to run • is able to represent realistic atmosphere-ocean coupling Atmosphere: • ECMWF single column model (SCM) Ocean: • single column KPP (K-Profile Parameterisation) mixed-layer ocean model

5. SCM: • based on the IFS code • includes a full set of physical parameterisations • we will use a stripped down version - adiabatic component (+ vertical diffusion?) • also want option to use full physics in later experiments KPP model: • developed at UoR • already within the SCM code but never been used • currently only works when full SCM physics scheme is switched on coupling through surface fluxes and SST

6. Progress so far • Successfully compiled and ran theSCM test-case provided by ECMWF. • Simplified the SCM code to remove physical parameterisations. • Tested the simplified atmospheric model using real data. • Coupled the KPP ocean code to the full-physics SCM and successfully ran a test case for the coupled atmosphere-ocean model. • Produced draft documentation for the models.

7. Issues • Lack of documentation • Choice of suitable test-case(s), creation of input file • Prescription of model forcing ocean: surface fluxes of heat, moisture & momentum, compute using bulk formulae of Large & Yeager atmosphere: vertical velocity, geostrophic u & v winds, horizontal advection tendencies. • Relaxation

8. SCM test-case: with (top) & without physics (bottom) temperature humidity u-wind v-wind

9. Relaxation of winds: u-wind with relaxation without relaxation

10. Issues • Lack of documentation • Choice of suitable test-case(s), creation of input file • Prescription of model forcing ocean: surface fluxes of heat, moisture & momentum, compute using bulk formulae of Large & Yeager atmosphere: vertical velocity, geostrophic u & v winds, horizontal advection tendencies. • Relaxation

11. ERA interim data: temperature actual SCM without forcing SCM with forcing

12. ERA interim data: humidity actual (log) SCM without forcing SCM with forcing

13. ERA interim data: u-wind actual SCM without forcing SCM with forcing

14. ERA interim data: v-wind actual SCM without forcing SCM with forcing

15. Coupled model: full physics

16. Coupled model: full physics

17. Coupled model: radiation, cloud & convection off

18. Coupled model: radiation, cloud & convection off

19. Next steps • Initial results with simple coupled atmosphere-ocean model expected by end of January 2013. • Development of prototype 4D-Var system - tangent linear and adjoint models preliminary results by April/May 2013. • Exploration of different coupling strategies being implemented in the ECMWF system - identical twin experiments