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Development of an atmospheric chemistry model coupled to the PALM model system 6.0: Implementation and first applications

Authors

Khan,  Basit
External Organizations;

Banzhaf,  Sabine
External Organizations;

/persons/resource/986

Chan,  Edward
IASS Institute for Advanced Sustainability Studies Potsdam;

Forkel,  Renate
External Organizations;

Kanani-Sühring,  Farah
External Organizations;

Ketelsen,  Klaus
External Organizations;

Kurppa,  Mona
External Organizations;

Maronga,  Björn
External Organizations;

Mauder,  Matthias
External Organizations;

Raasch,  Siegfried
External Organizations;

Russo,  Emmanuele
External Organizations;

Schaap,  Martijn
External Organizations;

Sühring,  Matthias
External Organizations;

External Ressource
No external resources are shared
Fulltext (public)

6000497.pdf
(Publisher version), 11MB

Supplementary Material (public)

6000497-supplement.pdf
(Supplementary material), 167KB

Citation

Khan, B., Banzhaf, S., Chan, E., Forkel, R., Kanani-Sühring, F., Ketelsen, K., Kurppa, M., Maronga, B., Mauder, M., Raasch, S., Russo, E., Schaap, M., Sühring, M. (2020 online): Development of an atmospheric chemistry model coupled to the PALM model system 6.0: Implementation and first applications. - Geoscientific model development discussions.
https://doi.org/10.5194/gmd-2020-286


Cite as: https://publications.iass-potsdam.de/pubman/item/item_6000497
Abstract
In this article we describe the implementation of an online-coupled gas-phase chemistry model in the turbulence resolving PALM model system 6.0. The new chemistry model is part of the PALM-4U components (read: PALM for you; PALM for urban applications) which are designed for application of PALM model in the urban environment (Maronga et al., 2020). The latest version of the Kinetic PreProcessor (KPP, 2.2.3), has been utilised for the numerical integration of gas-phase chemical5reactions. A number of tropospheric gas-phase chemistry mechanisms of different complexity have been implemented ranging from the photostationary state to more complex mechanisms such as CBM4, which includes major pollutants namely O3, NO, NO2, CO, a simplified VOC chemistry and a small number of products. Further mechanisms can also be easily added by the user. In this work, we provide a detailed description of the chemistry model, its structure along with its various features, input requirements, its application and limitations. A case study is presented to demonstrate the application of the new chemistry10model in the urban environment. The computation domain of the case study is comprised of part of Berlin, Germany, covering an area of 6.71 x 6.71 km with a horizontal resolution of 10 m. We used "PARAMETERIZED" emission mode of the chemistry model that only considers emissions from traffic sources. Three chemical mechanisms of varying complexity and one no-reaction (passive) case have been applied and results are compared with observations from two permanent air quality stations in Berlin that fall within the computation domain. The results show importance of online photochemistry and dispersion of air15pollutants in the urban boundary layer. The simulated NOx and O3species show reasonable agreement with observations. The agreement is better during midday and poorest during the evening transition hours and at night. CBM4 and SMOG mechanisms show better agreement with observations than the steady state PHSTAT mechanism.