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Radiative Transfer Model 3.0 integrated into the PALM model system 6.0
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SYSNO ASEP 0549609 Druh ASEP V - Výzkumná zpráva Zařazení RIV Záznam nebyl označen do RIV Název Radiative Transfer Model 3.0 integrated into the PALM model system 6.0 Tvůrce(i) Krč, Pavel (UIVT-O) SAI, RID, ORCID
Resler, Jaroslav (UIVT-O) SAI, RID, ORCID
Sühring, M. (DE)
Schubert, S. (DE)
Salim, M. (DE)
Fuka, V. (CZ)Vyd. údaje Mnichov: European Geosciences Union, 2021 Zdroj.dok. Geoscientific Model Development. - : Copernicus GmbH - ISSN 1991-959X
-, Accepted for review Aug 2020 (2021)Edice Geoscientific Model Development Discussions Č. sv. edice gmd-2020-168 Poč.str. 57 s. Forma vydání Online - E Jazyk dok. eng - angličtina Země vyd. DE - Německo Vědní obor RIV DG - Vědy o atmosféře, meteorologie Obor OECD Meteorology and atmospheric sciences CEP UH0383 GA KHP - Hlavní město Praha Institucionální podpora UIVT-O - RVO:67985807 DOI https://doi.org/10.5194/gmd-2020-168 Anotace The Radiative Transfer Model (RTM) is an explicitly resolved three-dimensional multi-reflection radiation model integrated into the PALM modelling system. It is responsible for modelling complex radiative interactions within the urban canopy. It represents a key component in modelling energy transfer inside the urban layer and consequently PALM's ability to provide explicit simulations of the urban canopy at metre-scale resolution. This paper presents RTM version 3.0, which is integrated into the PALM modelling system version 6.0. This version of RTM has been substantially improved over previous versions. A more realistic representation is enabled by the newly simulated processes, e.g. the interaction of longwave radiation with the plant canopy, evapotranspiration and latent heat flux, calculation of mean radiant temperature, and bidirectional interaction with the radiation forcing model. The new version also features novel discretization schemes and algorithms, namely the angular discretization and the azimuthal ray tracing, which offer significantly improved scalability and computational efficiency, enabling larger parallel simulations. It has been successfully tested on a realistic urban scenario with a horizontal size of over 6 million grid points using 8192 parallel processes. Pracoviště Ústav informatiky Kontakt Tereza Šírová, sirova@cs.cas.cz, Tel.: 266 053 800 Rok sběru 2022 Elektronická adresa http://dx.doi.org/10.5194/gmd-2020-168
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