Recent development of the Met Office operational ocean forecasting system: an overview and assessment of the new Global FOAM forecasts

Blockley, Ed; Martin, Matthew J.; McLaren, A. J.; Ryan, Andrew; Waters, Jennifer; Lea, Daniel; Mirouze, Isabelle; Peterson, K. Andrew; Sellar, Alistair; Storkey, David

doi:10.5194/gmd-7-2613-2014

Cited by 180 publications

(187 citation statements)

References 86 publications

Supporting

Mentioning

169

Contrasting

Order By: Relevance

“…It should be noted here that NEMO-LIM2 users can tune the total ice extent and volume by adjusting the parameter hiccrit (Wang et al, 2010), a characteristic thickness that is used to determine changes in open water area during ice growth. Nonetheless, overestimation of the total ice extent or volume is often reported in NEMO-related publications (Massonnet et al, 2011;Blockley et al, 2014), likely related to the use of a too-large value of the aforementioned parameter for given configuration and forcing. ORCA12-T321 used hiccrit = 0.6 m and the same value is applied in the CREG12 LIM2 runs.…”

Section: Lim2 and Cice Parametersmentioning

confidence: 99%

A high-resolution ocean and sea-ice modelling system for the Arctic and North Atlantic oceans

et al. 2015

View full text Add to dashboard Cite

Abstract. As part of the CONCEPTS (Canadian Operational Network of Coupled Environmental PredicTion Systems) initiative, a high-resolution (1/12 • ) ice-ocean regional model is developed covering the North Atlantic and the Arctic oceans. The long-term objective is to provide Canada with short-term ice-ocean predictions and hazard warnings in ice-infested regions. To evaluate the modelling component (as opposed to the analysis -or data-assimilation -component, which is not covered in this contribution), a series of hindcasts for the period 2003-2009 is carried out, forced at the surface by the Canadian GDPS reforecasts (Smith et al., 2014). These hindcasts test how the model represents upper ocean characteristics and ice cover. Each hindcast implements a new aspect of the modelling or the ice-ocean coupling. Notably, the coupling to the multi-category ice model CICE is tested. The hindcast solutions are then assessed using a verification package under development, including in situ and satellite ice and ocean observations. The conclusions are as follows: (1) the model reproduces reasonably well the time mean, variance and skewness of sea surface height; (2) the model biases in temperature and salinity show that while the mean properties follow expectations, the Pacific Water signature in the Beaufort Sea is weaker than observed; (3) the modelled freshwater content of the Arctic agrees well with observational estimates; (4) the distribution and volume of the sea ice are shown to be improved in the latest hindcast due to modifications to the drag coefficients and to some degree to the ice thickness distribution available in CICE; (5) nonetheless, the model still overestimates the ice drift and ice thickness in the Beaufort Gyre.

show abstract

Section: Lim2 and Cice Parametersmentioning

confidence: 99%

A high-resolution ocean and sea-ice modelling system for the Arctic and North Atlantic oceans

et al. 2015

View full text Add to dashboard Cite

show abstract

“…As part of the Forecasting Ocean Assimilation Model (FOAM; Blockley et al, 2014) suite of models, NEMO-ERSEM is run operationally at the Met Office on a daily basis, providing 5-day forecasts of physical and biogeochemical variables for the Northwest European Shelf seas. Analyses and forecasts are publicly available through the Copernicus Marine Environment Monitoring Service (CMEMS; http://marine.copernicus.eu), which is the operational service building on the MyOcean project.…”

Section: Nemo-ersemmentioning

confidence: 99%

Observing and modelling phytoplankton community structure in the North Sea

et al. 2017

View full text Add to dashboard Cite

Abstract. Phytoplankton form the base of the marine food chain, and knowledge of phytoplankton community structure is fundamental when assessing marine biodiversity. Policy makers and other users require information on marine biodiversity and other aspects of the marine environment for the North Sea, a highly productive European shelf sea. This information must come from a combination of observations and models, but currently the coastal ocean is greatly under-sampled for phytoplankton data, and outputs of phytoplankton community structure from models are therefore not yet frequently validated. This study presents a novel set of in situ observations of phytoplankton community structure for the North Sea using accessory pigment analysis. The observations allow a good understanding of the patterns of surface phytoplankton biomass and community structure in the North Sea for the observed months of August 2010 and 2011. Two physical-biogeochemical ocean models, the biogeochemical components of which are different variants of the widely used European Regional Seas Ecosystem Model (ERSEM), were then validated against these and other observations. Both models were a good match for sea surface temperature observations, and a reasonable match for remotely sensed ocean colour observations. However, the two models displayed very different phytoplankton community structures, with one better matching the in situ observations than the other. Nonetheless, both models shared some similarities with the observations in terms of spatial features and interannual variability. An initial comparison of the formulations and parameterizations of the two models suggests that diversity between the parameter settings of model phytoplankton functional types, along with formulations which promote a greater sensitivity to changes in light and nutrients, is key to capturing the observed phytoplankton community structure. These findings will help inform future model development, which should be coupled with detailed validation studies, in order to help facilitate the wider application of marine biogeochemical modelling to user and policy needs.

show abstract

“…GloSea5 [39] is an upgrade to GloSea4 including an increase to N216-ORCA025 resolution, with initial sea ice and ocean conditions now being provided by the NEMOVAR assimilation scheme [51] as configured for the FOAM ocean forecasting system [52].…”

Section: Appendix a Met Office Modelling Systems (A) Hadgem1mentioning

confidence: 99%

A seamless approach to understanding and predicting Arctic sea ice in Met Office modelling systems

Hewitt

Ridley

Keen

et al. 2015

Phil. Trans. R. Soc. A.

View full text Add to dashboard Cite

One contribution of 9 to a discussion meeting issue 'Arctic sea ice reduction: the evidence, models and impacts (part 1)' . Recent CMIP5 models predict large losses of summer Arctic sea ice, with only mitigation scenarios showing sustainable summer ice. Sea ice is inherently part of the climate system, and heat fluxes affecting sea ice can be small residuals of much larger air-sea fluxes. We discuss analysis of energy budgets in the Met Office climate models which point to the importance of early summer processes (such as clouds and meltponds) in determining both the seasonal cycle and the trend in ice decline. We give examples from Met Office modelling systems to illustrate how the seamless use of models for forecasting on time scales from short range to decadal might help to unlock the drivers of high latitude biases in climate models. Subject Areas: meteorology Keywords

show abstract

Recent development of the Met Office operational ocean forecasting system: an overview and assessment of the new Global FOAM forecasts

Cited by 180 publications

References 86 publications

A high-resolution ocean and sea-ice modelling system for the Arctic and North Atlantic oceans

A high-resolution ocean and sea-ice modelling system for the Arctic and North Atlantic oceans

Observing and modelling phytoplankton community structure in the North Sea

A seamless approach to understanding and predicting Arctic sea ice in Met Office modelling systems

Contact Info

Product

Resources

About