********************* Oceanic tracers (TOP) ********************* .. contents:: :local: TOP (Tracers in the Ocean Paradigm) is the NEMO hardwired interface toward biogeochemical models and provide the physical constraints/boundaries for oceanic tracers. It consists of a modular framework to handle multiple ocean tracers, including also a variety of built-in modules. This component of the NEMO framework allows one to exploit available modules (see below) and further develop a range of applications, spanning from the implementation of a dye passive tracer to evaluate dispersion processes (by means of MY_TRC), track water masses age (AGE module), assess the ocean interior penetration of persistent chemical compounds (e.g., gases like CFC or even PCBs), up to the full set of equations involving marine biogeochemical cycles. Structure ========= TOP interface has the following location in the source code ``./src/MBG/`` and the following modules are available: ``TRP`` Interface to NEMO physical core for computing tracers transport ``CFC`` Inert carbon tracers (CFC11,CFC12, SF6) ``C14`` Radiocarbon passive tracer ``AGE`` Water age tracking ``MY_TRC`` Template for creation of new modules and external BGC models coupling ``PISCES`` Built in BGC model. See [https://www.geosci-model-dev.net/8/2465/2015/gmd-8-2465-2015-discussion.html Aumont et al. (2015)] for a throughout description. | The usage of TOP is activated i) by including in the configuration definition the component ``MBG`` and ii) by adding the macro ``key_top`` in the configuration CPP file (see for more details [http://forge.ipsl.jussieu.fr/nemo/wiki/Users "Learn more about the model"]). As an example, the user can refer to already available configurations in the code, ``GYRE_PISCES`` being the NEMO biogeochemical demonstrator and ``GYRE_BFM`` to see the required configuration elements to couple with an external biogeochemical model (see also Section 4) . Note that, since version 4.0, TOP interface core functionalities are activated by means of logical keys and all submodules preprocessing macros from previous versions were removed. Here below the list of preprocessing keys that applies to the TOP interface (beside ``key_top``): ``key_iomput`` use XIOS I/O ``key_zdfddm`` & ``key_zdftke`` & ``key_zdfgls`` vertical schemes (need to be updated after Merge2017 finalization) ``key_trabbl`` bottom boundary layer parameterization ``key_agrif`` enable AGRIF coupling ``key_trdtrc`` & ``key_trdmxl_trc`` trend computation for tracers Synthetic Workflow ================== A synthetic description of the TOP interface workflow is given below to summarize the steps involved in the computation of biogeochemical and physical trends and their time integration and outputs, by reporting also the principal Fortran subroutine herein involved. **Model initialization (OPA_SRC/nemogcm.F90)** call to trc_init (trcini.F90) ↳ call trc_nam (trcnam.F90) to initialize TOP tracers and run setting ↳ call trc_ini_sms, to initialize each submodule ↳ call trc_ini_trp, to initialize transport for tracers ↳ call trc_ice_ini, to initialize tracers in seaice ↳ call trc_ini_state, read passive tracers from a restart or input data ↳ call trc_sub_ini, setup substepping if {{{nn_dttrc /= 1}}} **Time marching procedure (OPA_SRC/stp.F90)** call to trc_stp.F90 (trcstp.F90) ↳ call trc_sub_stp, averaging physical variables for sub-stepping ↳ call trc_wri, call XIOS for output of data ↳ call trc_sms, compute BGC trends for each submodule ↳ call trc_sms_my_trc, includes also surface and coastal BCs trends ↳ call trc_trp (TRP/trctrp.F90), compute physical trends ↳ call trc_sbc, get trend due to surface concentration/dilution ↳ call trc_adv, compute tracers advection ↳ call to trc_ldf, compute tracers lateral diffusion ↳ call to trc_zdf, vertical mixing and after tracer fields ↳ call to trc_nxt, tracer fields at next time step. Lateral Boundary Conditions are solved in here. ↳ call to trc_rad, Correct artificial negative concentrations ↳ call trc_rst_wri, output tracers restart files Namelists walkthrough ===================== namelist_top ------------ Here below are listed the features/options of the TOP interface accessible through the namelist_top_ref and modifiable by means of namelist_top_cfg (as for NEMO physical ones). Note that ## is used to refer to a number in an array field. .. literalinclude:: ../../namelists/namtrc_run .. literalinclude:: ../../namelists/namtrc .. literalinclude:: ../../namelists/namtrc_dta .. literalinclude:: ../../namelists/namtrc_adv .. literalinclude:: ../../namelists/namtrc_ldf .. literalinclude:: ../../namelists/namtrc_rad .. literalinclude:: ../../namelists/namtrc_dmp .. literalinclude:: ../../namelists/namtrc_ice .. literalinclude:: ../../namelists/namtrc_trd .. literalinclude:: ../../namelists/namtrc_bc .. literalinclude:: ../../namelists/namtrc_bdy .. literalinclude:: ../../namelists/namage Two main types of data structure are used within TOP interface to initialize tracer properties (1) and to provide related initial and boundary conditions (2). **1. TOP tracers initialization**: sn_tracer (namtrc) Beside providing name and metadata for tracers, here are also defined the use of initial ({{{sn_tracer%llinit}}}) and boundary ({{{sn_tracer%llsbc, sn_tracer%llcbc, sn_tracer%llobc}}}) conditions. In the following, an example of the full structure definition is given for two idealized tracers both with initial conditions given, while the first has only surface boundary forcing and the second both surface and coastal forcings: .. code-block:: fortran ! ! name ! title of the field ! units ! initial data ! sbc ! cbc ! obc ! sn_tracer(1) = 'TRC1' , 'Tracer 1 Concentration ', ' - ' , .true. , .true., .false., .true. sn_tracer(2) = 'TRC2 ' , 'Tracer 2 Concentration ', ' - ' , .true. , .true., .true. , .false. As tracers in BGC models are increasingly growing, the same structure can be written also in a more compact and readable way: .. code-block:: fortran ! ! name ! title of the field ! units ! initial data ! sn_tracer(1) = 'TRC1' , 'Tracer 1 Concentration ', ' - ' , .true. sn_tracer(2) = 'TRC2 ' , 'Tracer 2 Concentration ', ' - ' , .true. ! sbc sn_tracer(1)%llsbc = .true. sn_tracer(2)%llsbc = .true. ! cbc sn_tracer(2)%llcbc = .true. The data structure is internally initialized by code with dummy names and all initialization/forcing logical fields set to .false. . **2. Structures to read input initial and boundary conditions**: namtrc_dta (sn_trcdta), namtrc_bc (sn_trcsbc/sn_trccbc/sn_trcobc) The overall data structure (Fortran type) is based on the general one defined for NEMO core in the SBC component (see details in User Manual SBC Chapter on Input Data specification). Input fields are prescribed within namtrc_dta (with sn_trcdta structure), while Boundary Conditions are applied to the model by means of namtrc_bc, with dedicated structure fields for surface (sn_trcsbc), riverine (sn_trccbc), and lateral open (sn_trcobc) boundaries. The following example illustrates the data structure in the case of initial condition for a single tracer contained in the file named tracer_1_data.nc (.nc is implicitly assumed in namelist filename), with a doubled initial value, and located in the usr/work/model/inputdata/ folder: .. code-block:: fortran ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask ! ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename ! sn_trcdta(1) = 'tracer_1_data' , -12 , 'TRC1' , .false. , .true. , 'yearly' , '' , '' , '' rf_trfac(1) = 2.0 cn_dir = “usr/work/model/inputdata/” Note that, the Lateral Open Boundaries conditions are applied on the segments defined for the physical core of NEMO (see BDY description in the User Manual). namelist_trc ------------ Here below the description of namelist_trc_ref used to handle Carbon tracers modules, namely CFC and C14. |||| &'''namcfc''' ! CFC || |||| &'''namc14_typ''' ! C14 - type of C14 tracer, default values of C14/C and pco2 || |||| &'''namc14_sbc''' ! C14 - surface BC || |||| &'''namc14_fcg''' ! files & dates || ``MY_TRC`` interface for coupling external BGC models ===================================================== The generalized interface is pivoted on MY_TRC module that contains template files to build the coupling between NEMO and any external BGC model. The call to MY_TRC is activated by setting ``ln_my_trc = .true.`` (in namtrc) The following 6 fortran files are available in MY_TRC with the specific purposes here described. ``par_my_trc.F90`` This module allows to define additional arrays and public variables to be used within the MY_TRC interface ``trcini_my_trc.F90`` Here are initialized user defined namelists and the call to the external BGC model initialization procedures to populate general tracer array (trn and trb). Here are also likely to be defined suport arrays related to system metrics that could be needed by the BGC model. ``trcnam_my_trc.F90`` This routine is called at the beginning of trcini_my_trc and should contain the initialization of additional namelists for the BGC model or user-defined code. ``trcsms_my_trc.F90`` The routine performs the call to Boundary Conditions and its main purpose is to contain the Source-Minus-Sinks terms due to the biogeochemical processes of the external model. Be aware that lateral boundary conditions are applied in trcnxt routine. IMPORTANT: the routines to compute the light penetration along the water column and the tracer vertical sinking should be defined/called in here, as generalized modules are still missing in the code. ``trcice_my_trc.F90`` Here it is possible to prescribe the tracers concentrations in the seaice that will be used as boundary conditions when ice melting occurs (nn_ice_tr =1 in namtrc_ice). See e.g. the correspondent PISCES subroutine. ``trcwri_my_trc.F90`` This routine performs the output of the model tracers (only those defined in namtrc) using IOM module (see Manual Chapter “Output and Diagnostics”). It is possible to place here the output of additional variables produced by the model, if not done elsewhere in the code, using the call to iom_put. Coupling an external BGC model using NEMO framework =================================================== The coupling with an external BGC model through the NEMO compilation framework can be achieved in different ways according to the degree of coding complexity of the Biogeochemical model, like e.g., the whole code is made only by one file or it has multiple modules and interfaces spread across several subfolders. Beside the 6 core files of MY_TRC module, let’s assume an external BGC model named *MYBGC* and constituted by a rather essential coding structure, likely few Fortran files. The new coupled configuration name is *NEMO_MYBGC*. The best solution is to have all files (the modified ``MY_TRC`` routines and the BGC model ones) placed in a unique folder with root ``MYBGCPATH`` and to use the makenemo external readdressing of ``MY_SRC`` folder. The coupled configuration listed in ``work_cfgs.txt`` will look like :: NEMO_MYBGC OPA_SRC TOP_SRC and the related ``cpp_MYBGC.fcm`` content will be .. code-block:: perl bld::tool::fppkeys key_zdftke key_dynspg_ts key_iomput key_mpp_mpi key_top the compilation with ``makenemo`` will be executed through the following syntax .. code-block:: console $ makenemo -n 'NEMO_MYBGC' -m '' -j 8 -e '' The makenemo feature “-e” was introduced to readdress at compilation time the standard MY_SRC folder (usually found in NEMO configurations) with a user defined external one. The compilation of more articulated BGC model code & infrastructure, like in the case of BFM ([http://www.bfm-community.eu/publications/bfmnemomanual_r1.0_201508.pdf BFM-NEMO coupling manual]), requires some additional features. As before, let’s assume a coupled configuration name *NEMO_MYBGC*, but in this case MYBGC model root becomes ```` that contains 4 different subfolders for biogeochemistry, named ``initialization``, ``pelagic``, and ``benthic``, and a separate one named ``nemo_coupling`` including the modified ``MY_SRC`` routines. The latter folder containing the modified NEMO coupling interface will be still linked using the makenemo “-e” option. In order to include the BGC model subfolders in the compilation of NEMO code, it will be necessary to extend the configuration ``cpp_NEMO_MYBGC.fcm`` file to include the specific paths of ``MYBGC`` folders, as in the following example .. code-block:: perl bld::tool::fppkeys key_zdftke key_dynspg_ts key_iomput key_mpp_mpi key_top src::MYBGC::initialization /initialization src::MYBGC::pelagic /pelagic src::MYBGC::benthic /benthic bld::pp::MYBGC 1 bld::tool::fppflags::MYBGC %FPPFLAGS bld::tool::fppkeys %bld::tool::fppkeys MYBGC_MACROS where *MYBGC_MACROS* is the space delimited list of macros used in *MYBGC* model for selecting/excluding specific parts of the code. The BGC model code will be preprocessed in the configuration ``BLD`` folder as for NEMO, but with an independent path, like ``NEMO_MYBGC/BLD/MYBGC/``. The compilation will be performed similarly to in the previous case with the following .. code-block:: console $ makenemo -n 'NEMO_MYBGC' -m '' -j 8 -e '/nemo_coupling' Note that, the additional lines specific for the BGC model source and build paths can be written into a separate file, e.g. named ``MYBGC.fcm``, and then simply included in the ``cpp_NEMO_MYBGC.fcm`` as follow .. code-block:: perl bld::tool::fppkeys key_zdftke key_dynspg_ts key_iomput key_mpp_mpi key_top inc /MYBGC.fcm This will enable a more portable compilation structure for all MYBGC related configurations. **Important**: the coupling interface contained in nemo_coupling cannot be added using the FCM syntax, as the same files already exists in NEMO and they are overridden only with the readdressing of MY_SRC contents to avoid compilation conflicts due to duplicate routines. All modifications illustrated above, can be easily implemented using shell or python scripting to edit the NEMO configuration CPP.fcm file and to create the BGC model specific FCM compilation file with code paths.