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Everything about Clams totally explainedCLaMS ( Chemical Lagrangian Model of the Stratosphere) is a modular chemistry transport model (CTM) system developed at Research Centre Jülich, Germany. CLaMS was first described byMcKenna et al (2000a,b) and was expanded into three dimensions by Konopka et al (2004). CLaMS has been employed in recent European field campaigns THESEO, EUPLEX, TROCCINOX and SCOUT-O3 with a focus on simulating ozone depletion and water vapour transport.
Unlike other CTMs (for example SLIMCAT, REPROBUS), CLaMS operates on a Lagrangian model grid (see section about model grids in general circulation model): an air parcel is described by three space coordinates and a time coordinate. The time evolution path that an air parcels traces in space is called a trajectory. A specialised mixing scheme ensures that physically realistic diffusion is imposed on an ensemble of
trajectories in regions of high wind shear.
CLaMS operates on arbitrarily resolved horizontal grids. The space coordinates are latitude, longitude and potential temperature.
Major strengths of CLaMS in comparison to other CTMs are
- its applicability for reverse domain filling studies
- its anisotropic mixing scheme
- its integrability with arbitrary observational data
- its comprehensive chemistry scheme
CLaMS Hierarchy
CLaMS is composed of four modules and several preprocessors. The four modules are
a trajectory module
a box chemistry module
a Lagrangian mixing module
a Lagrangian sedimentation scheme
Trajectory module
Integration of trajectories with 4th order Runge-Kutta method, integration time step 30 minutes. Vertical displacement of trajectories is calculated from radiation budget.
Box chemistry module
Chemistry is based on the ASAD chemistry code of the [[Universityof
Cambridge]]. More than 100 chemical reactions involving 40+ chemical
species are considered. Integration time step is 10 minutes, species
can be combined into chemical families to facilitate integration. The
module includes a radiative transfer model for the determination of
photolysis rates. The module also includes heterogeneous reactions on
NAT, ice and liquid particle surfaces.
Lagrangian mixing
Mixing is based on grid deformation of quasi uniform air parcel
distributions. The contraction or elongation factors of the distances
to neighboring air parcels are examined: if a critical elongation
(contraction) is reached, new air parcels are introduced (taken away).
This way, anisotropic diffusion is simulated in a physically realistic
manner.
Lagrangian sedimentation
Lagrangian sedimentation is calculated by following individual nitric
acid trihydrate (NAT) particles that may grow or shrink by the uptake
or release of HNO3 from/to the gas phase. These particle parcels are
simulated independently from the Lagrangian air parcels. Their
trajectories are determined using the horizontal winds and their
vertical settling velocity that depends on the size of the individual
particles. NAT particles are nucleated assuming a constant nucleation
rate and they evaporate where temperatures grow too high. With this,
a vertical redistribution of HNO3 (denitrification and
renitrification) is determined.
CLaMS data sets
A chemistry transport model doesn't simulate the dynamics of the atmosphere. For CLaMS, the following meteorological data sets have been used
European Centre for Medium-Range Weather Forecasts (ECMWF), Predictions, Analyses, ERA-15, ERA40
United Kingdom Meteorological Office (UKMO)
European Centre Hamburg Atmospheric Model (ECHAM4), in the DLR version
To initialize the chemical fields in CLaMS, data from a large variety of instruments have provided data.
on satellite (CRISTA, MIPAS, MLS, HALOE, ILAS, ...),
on aircraft and balloons (HALOX, FISH, Mark IV, BONBON...)
If no observations are present, the chemical fields can be initialised
from two-dimensional chemical models, chemistry-climate models,
climatologies, or from correlations between chemical species or
chemical species and dynamical variables.
Further Information
Get more info on 'Clams'.
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