1Department of Earth Science and Engineering, Imperial College London, London, UK
2Scientific Computing, Simula Research Laboratory, Fornebu, Norway
3Environment Department, University of York, York, UK
4Grantham Institute – Climate Change and the Environment, Imperial College London, London, UK
Received: 26 May 2016 – Discussion started: 13 Jul 2016
Abstract. Turbidity currents are one of the main drivers of sediment transport from the continental shelf to the deep ocean. The resulting sediment deposits can reach hundreds of kilometres into the ocean. Computer models that simulate turbidity currents and the resulting sediment deposit can help us to understand their general behaviour. However, in order to recreate real-world scenarios, the challenge is to find the turbidity current parameters that reproduce the observations of sediment deposits.
Revised: 06 Jan 2017 – Accepted: 08 Feb 2017 – Published: 07 Mar 2017
This paper demonstrates a solution to the inverse sediment transportation problem: for a known sedimentary deposit, the developed model reconstructs details about the turbidity current that produced the deposit. The reconstruction is constrained here by a shallow water sediment-laden density current model, which is discretised by the finite-element method and an adaptive time-stepping scheme. The model is differentiated using the adjoint approach, and an efficient gradient-based optimisation method is applied to identify the turbidity parameters which minimise the misfit between the modelled and the observed field sediment deposits. The capabilities of this approach are demonstrated using measurements taken in the Miocene Marnoso-arenacea Formation (Italy). We find that whilst the model cannot match the deposit exactly due to limitations in the physical processes simulated, it provides valuable insights into the depositional processes and represents a significant advance in our toolset for interpreting turbidity current deposits.
Parkinson, S. D., Funke, S. W., Hill, J., Piggott, M. D., and Allison, P. A.: Application of the adjoint approach to optimise the initial conditions of a turbidity current with the AdjointTurbidity 1.0 model, Geosci. Model Dev., 10, 1051-1068, doi:10.5194/gmd-10-1051-2017, 2017.