Implementation of IFS cycle 48r1 for CAMS

Description of upgrade

The CAMS IFS cycle 48R1 is based on ECMWF's  IFS cycle 48R1 . This is a major upgrade with various scientific contributions. Key elements are the addition of full stratospheric chemistry, changes to the modelling of dust aerosol resulting in a redistribution of aerosol particles towards larger sizes and therefore a significant increase in global dust mass burden, and the addition of two new aerosol species (anthropogenic and biogenic secondary organic aerosol). In addition, four new species have been added to the tropospheric chemistry scheme, and prescribed emissions have been updated to more recent versions. In terms of technical changes, there is an important change to the GRIB encoding. More information can be found below.

The page will be updated as required. It was last changed on 25 April 2023.

For a record of changes made to this page please refer to Document versions .

Further information and advice regarding the upgrade can be obtained from the Copernicus User Support.

Timetable for implementation

The planned timetable for the implementation of the cycle 47r3 is as follows:

The timetable represents current expectations and may change in light of actual progress made

Current Status

IFS cycle 48r1 is going through its final preparation phase.

Meteorological content of the new cycle

The meteorological changes can be found on the ECMWF  IFS CY48R1 page.

Atmospheric composition content of the new cycle

Assimilation

• Instrument specific bias correction for AOD
• Data assimilation for separate volcanic SO2 tracer (optional) 
• Enable modification Nitrate and Ammonium aerosols by data assimilation (bugfix)  

Observations

• Activation of assimilation of Sentinel-5p/TropOMI CO retrievals 
• AOD from VIIRS (activated already in 47r3 1.2.2023) 
• Passive monitoring of IASI SO2 retrievals 

Emissions

• CAMS_GLOB_ANT v5.3 with sectoral diurnal cycles and injection heights
• CAMS_GLOB_BIO v3.1 climatology
• CAMS_GLOB_OCE v.3.1 climatology DMS
• CAMS_GLOB_AIR v3.1 CO2/NOx  (aircraft)
• Using IS4FIRES injection heights (from GFAS version 1.4)
• Sector-specific emission input to the IFS and application of sector specific injection height ranges and diurnal cycle profiles 
• Natural emissions as as used previously 

Model changes

• Activation of stratosphere chemistry using the BASCOE scheme - adding 63 reactive gas species 
• New tropospheric species: HCN, CH3CN, Glyoxal and Glycoladehyde
• Improved isoprene oxidation simulation
• Update of dry deposition formulation for reactive gases 
• Two new secondary organic aerosol tracers (anthropogenic and biogenic) and respective precursor gas tracers 
• Major update of dust emissions and removal simulation (resulting in a redistribution of dust aerosol towards larger particles with an increase in the global dust mass burden by a factor of 2 as a result)   
• Review of aerosol optical properties (dust , brown carbon) 
• Improved secondary inorganic aerosol simulation 
• Use of COMADH advection for aerosols, reactive gases and GHG

Impact of the new cycle

A comprehensive evaluation report of the 48r1 e-suite, documenting all the changes and their impact on the forecasts, is in preparation and will be provided before the implementation date. Based on the evaluation of the testing of all individual changes and the preliminary evaluation of the final e-suite, the following aspects for key species should be noted:

• New aerosol species added (anthropogenic and biogenic secondary organic aerosol)
• New tropospheric chemical species added (HCN, CH₃CN, Glyoxal and Glycoladehyde)
• Comprehensive stratospheric chemistry added (including 63 species)
• Stratospheric ozone (O₃): improvement in lower stratosphere with slight degradation in tropical upper stratosphere
• Stratospheric nitrogen dioxide (NO₂): significant improvement due to more comprehensive chemistry
• Tropospheric ozone (O₃): generally neutral with positive impact in south-east Asia
• Tropospheric nitrogen dioxide (NO₂): generally small improvement, which is more pronounced for south-east Asia
• Tropospheric sulfur dioxide (SO₂): generally small improvement, which is more pronounced for south-east Asia
• Tropospheric carbon monoxide (CO): generally small improvement, which is more pronounced for south-east Asia
• Surface NO₂ and SO₂: decrease in surface concentrations leading mainly to reduced biases in Europe, North-America and Europe , especially for background stations.
• UV: no major change
  
• Aerosol Optical Depth (AOD): no major change
• Dust aerosol: redistribution of aerosol particles towards larger sizes and therefore a significant increase in global dust mass burden
• PM2.5: reduced over North-America and China but not in Europe. This means a now negative bias over North America and China, which is expected for a global model that does not resolve detailed polluted areas.

Technical details of the new cycle

New and discontinued parameters

Several of the upgrades in CY48R1 have resulted in new parameters, some of which will be added to the dissemination through the Atmosphere Data Store (ADS) and the ECPDS ftp server. For now, the main new parameters are listed in the table below. Others might be added based on user requests.

Change to GRIB encoding

The GRIB model identifiers (generating process identification number) for cycle 48r1 will be changed as follows:

For gridded 48r1 model output in GRIB 2 format the packing type will change as follows: 

With the introduction of the new CCSDS packing type the default behaviour in dissemination and MARS (from 14 March) will be as follows: 

This implies that by default only fields derived from gridded GRIB2 fields from 48r1 onwards will use packing type CCSDS. The default behaviour can be overridden by specifying the packing explicitly, e.g.  

  grid    = 0.1/0.1, 
  packing = CCSDS 

will deliver fields with CCSDS packing for any GRIB2 input field. It will however not be possible to get CCSDS packed fields from GRIB1 input fields. Similarly, if CCSDS compression is not desired when retrieving gridded GRIB 2 fields from MARS or dissemination, simple packing can be requested with keyword 

  packing = simple 

Using ecCodes, already retrieved CCSDS compressed fields can be converted to other packing types. This is how to convert all messages in file ccsds.grib with grid_ccsds as their packingType, and only those, to use simple packing, i.e. what we used before 48r1: 

  grib_set -r -w packingType=grid_ccsds -s packingType=grid_simple ccsds.grib grid_simple.grib

To compare the statistics of the fields before and after the conversion, the following command could be used:

  grib_ls -n statistics ccsds.grib grid_simple.grib

Software

The software packages listed below are recommended for full support for all 48r1 parameters and the new CCSDS compression. 

ecCodes 2.28.0
Magics 4.13.0
Metview 5.18.0

On the ECMWF Atos system these packages can be loaded via the module ecmwf-toolbox/2023.01.0.0. Before the implementation software versions compatible with 48r1 will be made the default on ECMWF platforms. 

Users are strongly encouraged to test their software applications and data processing chain with the new versions of the various software packages before this change. 

Availability of test data from the cycle 48r1 test suites

The CAMS operational FTP server (ECPDS) will serve the most recent 3 days of test data, once the e-suite is running in near-real-time, in the directories "/DATA/CAMS_GLOBAL_TEST" and "/DATA/CAMS_EUROPE_BC_TEST" for global and regional boundary condition data, respectively. In addition, surface level fields (model level 137) will be provided as individual files in the "/DATA/CAMS_GLOBAL_ADDITIONAL_TEST" directory. Users wanting to access the output from the current test system for a longer period can access the data from 1 September 2022 onwards directly on MARS or through. More details can be found here: Accessing CAMS 48r1 test data.

Document versions