Browsing by Author "Zhang, K"

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    Evaluate transport processes in MERRA driven chemical transport models using updated 222Rn emission inventories and global observations
    (AGU, 2015-12-14) Zhang, B; Liu, HY; Crawford, J; Fairlie, TD; Chen, G; Chambers, SD; Kang, CH; Williams, AG; Zhang, K; Considine, DB; Sulprizio, MP; Yantosca, RM
    Convective and synoptic processes play a major role in determining the transport and distribution of trace gases and aerosols in the troposphere. The representation of these processes in global models (at ~100-1000 km horizontal resolution) is challenging, because convection is a sub-grid process and needs to be parameterized, while synoptic processes are close to the grid scale. Depending on the parameterization schemes used in climate models, the role of convection in transporting trace gases and aerosols may vary from model to model. 222Rn is a chemically inert and radioactive gas constantly emitted from soil and has a half-life (3.8 days) comparable to synoptic timescale, which makes it an effective tracer for convective and synoptic transport. In this study, we evaluate the convective and synoptic transport in two chemical transport models (GMI and GEOS-Chem), both driven by the NASA’s MERRA reanalysis. Considering the uncertainties in 222Rn emissions, we incorporate two more recent scenarios with regionally varying 222Rn emissions into GEOS-Chem/MERRA and compare the simulation results with those using the relatively uniform 222Rn emissions in the standard model. We evaluate the global distribution and seasonality of 222Rn concentrations simulated by the two models against an extended collection of 222Rn observations from 1970s to 2010s. The intercomparison will improve our understanding of the spatial variability in global 222Rn emissions, including the suspected excessive 222Rn emissions in East Asia, and provide useful feedbacks on 222Rn emission models. We will assess 222Rn vertical distributions at different latitudes in the models using observations at surface sites and in the upper troposphere and lower stratosphere. Results will be compared with previous models driven by other meteorological fields (e.g., fvGCM and GEOS4). Since the decay of 222Rn is the source of 210Pb, a useful radionuclide tracer attached to submicron aerosols, improved understanding of emissions and transport of 222Rn will provide insights into the transport, distribution, and wet deposition of 210Pb aerosols.
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    Radon activity in the lower troposphere and its impact on ionization rate: a global estimate using different radon emissions
    (European Geosciences Union, 2011-01-01) Zhang, K; Feichter, J; Kazil, J; Wan, H; Zhuo, W; Griffiths, AD; Sartorius, H; Zahorowski, W; Ramonet, M; Schmidt, M; Yver, C; Neubert, REM; Brunke, EG
    The radioactive decay of radon and its progeny can lead to ionization of air molecules and consequently influence aerosol size distribution. In order to provide a global estimate of the radon-related ionization rate, we use the global atmospheric model ECHAM5 to simulate transport and decay processes of the radioactive tracers. A global radon emission map is put together using regional fluxes reported recently in the literature. Near-surface radon concentrations simulated with this new map compare well with measurements. Radon-related ionization rate is calculated and compared to that caused by cosmic rays. The contribution of radon and its progeny clearly exceeds that of the cosmic rays in the mid- and low-latitude land areas in the surface layer. During cold seasons, at locations where high concentration of sulfuric acid gas and low temperature provide potentially favorable conditions for nucleation, the coexistence of high ionization rate may help enhance the particle formation processes. This suggests that it is probably worth investigating the impact of radon-induced ionization on aerosol-climate interaction in global models. © Author(s) 2011.
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    Simulation of radon-222 with the GEOS-Chem global model: emissions, seasonality, and convective transport
    (Copernicus Publications, 2021-02-10) Zhang, B; Liu, HY; Crawford, JH; Chen, G; Fairlie, TD; Chambers, SD; Kang, CH; Williams, AG; Zhang, K; Considine, DB; Sulprizio, MP; Yantosca, RM
    Radon-222 (222Rn) is a short-lived radioactive gas naturally emitted from land surfaces and has long been used to assess convective transport in atmospheric models. In this study, we simulate 222Rn using the GEOS-Chem chemical transport model to improve our understanding of 222Rn emissions and surface concentration seasonality and characterize convective transport associated with two Goddard Earth Observing System (GEOS) meteorological products, the Modern-Era Retrospective analysis for Research and Applications (MERRA) and GEOS Forward Processing (GEOS-FP). We evaluate four global 222Rn emission scenarios by comparing model results with observations at 51 surface sites. The default emission scenario in GEOS-Chem yields a moderate agreement with surface observations globally (68.9 % of data within a factor of 2) and a large underestimate of winter surface 222Rn concentrations at Northern Hemisphere midlatitudes and high latitudes due to an oversimplified formulation of 222Rn emission fluxes (1 atom cm−2 s−1 over land with a reduction by a factor of 3 under freezing conditions). We compose a new global 222Rn emission scenario based on Zhang et al. (2011) and demonstrate its potential to improve simulated surface 222Rn concentrations and seasonality. The regional components of this scenario include spatially and temporally varying emission fluxes derived from previous measurements of soil radium content and soil exhalation models, which are key factors in determining 222Rn emission flux rates. However, large model underestimates of surface 222Rn concentrations still exist in Asia, suggesting unusually high regional 222Rn emissions. We therefore propose a conservative upscaling factor of 1.2 for 222Rn emission fluxes in China, which was also constrained by observed deposition fluxes of 210Pb (a progeny of 222Rn). With this modification, the model shows better agreement with observations in Europe and North America (> 80 % of data within a factor of 2) and reasonable agreement in Asia (close to 70 %). Further constraints on 222Rn emissions would require additional concentration and emission flux observations in the central United States, Canada, Africa, and Asia. We also compare and assess convective transport in model simulations driven by MERRA and GEOS-FP using observed 222Rn vertical profiles in northern midlatitude summer and from three short-term airborne campaigns. While simulations with both GEOS products are able to capture the observed vertical gradient of 222Rn concentrations in the lower troposphere (0–4 km), neither correctly represents the level of convective detrainment, resulting in biases in the middle and upper troposphere. Compared with GEOS-FP, MERRA leads to stronger convective transport of 222Rn, which is partially compensated for by its weaker large-scale vertical advection, resulting in similar global vertical distributions of 222Rn concentrations between the two simulations. This has important implications for using chemical transport models to interpret the transport of other trace species when these GEOS products are used as driving meteorology. © Author(s) 2021.
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    Status of the compactlight design study
    (JACoW Publishing, 2019-05-19) D'Auria, G; Mitri, SD; Rochow, RA; Latina, A; Liu, X; Rossi, C; Schulte, D; Stapnes, S; Wu, X; Castañeda Cortes, HM; Clarke, J; Dunning, DJ; Thompson, N; Fang, W; Gazis, E; Gazis, N; Tanke, E; Trachnas, E; Goryashko, V; Jacewicz, M; Ruber, R; Taylor, G; Dowd, RT; Zhu, D; Aksoy, A; Nergiz, Z; Apsimon, R; Burt, G; Castilla, A; Priem, H; Janssen, X; Luiten, J; Mutsaers, P; Stragier, X; Alesini, D; Bellaveglia, M; Buonomo, B; Cardelli, F; Croia, M; Diomede, M; Ferrario, M; Gallo, A; Giribono, A; Piersanti, L; Scifo, J; Spataro, B; Vaccarezza, C; Geometrante, R; Kokole, M; Arnesano, J; Bosco, F; Ficcadenti, L; Mostacci, A; Palumbo, L; Dattoli, G; Nguyen, F; Petralia, A; Marcos, J; Marín, E; Muñoz Horta, R; Perez, F; Faus-Golfe, A; Han, Y; Bernhard, A; Gethmann, J; Calvi, M; Schmidt, T; Zhang, K; Esperante, D; Fuster, J; Gimeno, B; Gonzalez-Iglesias, D; Aicheler, M; Hoekstra, R; Cross, AW; Nix, L; Zhang, L
    CompactLight (XLS) is an International Collaboration of 24 partners and 5 third parties, funded by the European Union through the Horizon 2020 Research and Innovation Programme. The main goal of the project, which started in January 2018 with a duration of 36 months, is the design of an hard X-ray FEL facility beyond today’s state of the art, using the latest concepts for bright electron photo-injectors, high-gradient accelerating structures, and innovative shortperiod undulators. The specifications of the facility and the parameters of the future FEL are driven by the demands of potential users and the associated science cases. In this paper we will give an overview on the ongoing activities and the major results achieved until now. © The Authors - CC-BY 3.0 licence