58 citations as recorded by crossref.

1. Recent advances in the study of mercury biogeochemistry in Arctic permafrost ecosystems B. Malcata Martins et al.
2. Challenges in simulating ozone depletion events in the Arctic boundary layer: a case study using ECHAM/MESSy for spring 2019/2020 S. Falk et al.
3. Role of the boundary layer in the occurrence and termination of the tropospheric ozone depletion events in polar spring L. Cao et al.
4. Implementation and Impacts of Surface and Blowing Snow Sources of Arctic Bromine Activation Within WRF‐Chem 4.1.1 L. Marelle et al.
5. Study of an Arctic blowing snow-induced bromine explosion event in Ny-Ålesund, Svalbard D. Chen et al.
6. Urban Snowpack ClNO2 Production and Fate: A One-Dimensional Modeling Study S. Wang et al.
7. Horizontal and vertical structure of reactive bromine events probed by bromine monoxide MAX-DOAS W. Simpson et al.
8. A case study of a transported bromine explosion event in the Canadian high arctic X. Zhao et al.
9. Understanding mercury oxidation and air–snow exchange on the East Antarctic Plateau: a modeling study S. Song et al.
10. Air–surface exchange of gaseous mercury over permafrost soil: an investigation at a high-altitude (4700 m a.s.l.) and remote site in the central Qinghai–Tibet Plateau Z. Ci et al.
11. Impact of shrub branches on the shortwave vertical irradiance profile in snow F. Domine et al.
12. Fostering multidisciplinary research on interactions between chemistry, biology, and physics within the coupled cryosphere-atmosphere system J. Thomas et al.
13. Arctic mercury cycling A. Dastoor et al.
14. Arctic springtime observations of volatile organic compounds during the OASIS‐2009 campaign R. Hornbrook et al.
15. Tropospheric Halogen Chemistry: Sources, Cycling, and Impacts W. Simpson et al.
16. Active molecular iodine photochemistry in the Arctic A. Raso et al.
17. Molecular Halogens Above the Arctic Snowpack: Emissions, Diurnal Variations, and Recycling Mechanisms S. Wang & K. Pratt
18. Dependence of the vertical distribution of bromine monoxide in the lower troposphere on meteorological factors such as wind speed and stability P. Peterson et al.
19. Parameterization of gaseous dry deposition in atmospheric chemistry models: Sensitivity to aerodynamic resistance formulations under statically stable conditions K. Toyota et al.
20. Near surface oxidation of elemental mercury leads to mercury exposure in the Arctic Ocean biota S. Lim et al.
21. Derivation of the reduced reaction mechanisms of ozone depletion events in the Arctic spring by using concentration sensitivity analysis and principal component analysis L. Cao et al.
22. Ozone depletion events in the Arctic spring of 2019: a new modeling approach to bromine emissions M. Herrmann et al.
23. Air–snowpack exchange of bromine, ozone and mercury in the springtime Arctic simulated by the 1-D model PHANTAS – Part 2: Mercury and its speciation K. Toyota et al.
24. Modelling the physical multiphase interactions of HNO3 between snow and air on the Antarctic Plateau (Dome C) and coast (Halley) H. Chan et al.
25. Sea-ice-related halogen enrichment at Law Dome, coastal East Antarctica P. Vallelonga et al.
26. Physical Characterization of Frozen Saltwater Solutions Using Raman Microscopy P. Malley et al.
27. The interplay between snow and polluted air masses in cold urban environments J. Kuhn et al.
28. Dynamics of ozone and nitrogen oxides at Summit, Greenland. II. Simulating snowpack chemistry during a spring high ozone event with a 1-D process-scale model K. Murray et al.
29. Multiphase Reactive Bromine Chemistry during Late Spring in the Arctic: Measurements of Gases, Particles, and Snow D. Jeong et al.
30. Bromine atom production and chain propagation during springtime Arctic ozone depletion events in Barrow, Alaska C. Thompson et al.
31. Arctic halogens reduce ozone in the northern mid-latitudes R. Fernandez et al.
32. Study of an Arctic Cyclone-Induced Bromine Explosion Event in Ny-Ålesund, Svalbard D. Chen et al.
33. Time-dependent 3D simulations of tropospheric ozone depletion events in the Arctic spring using the Weather Research and Forecasting model coupled with Chemistry (WRF-Chem) M. Herrmann et al.
34. Modelling the coupled mercury-halogen-ozone cycle in the central Arctic during spring S. Ahmed et al.
35. Polar boundary layer bromine explosion and ozone depletion events in the chemistry–climate model EMAC v2.52: implementation and evaluation of AirSnow algorithm S. Falk & B. Sinnhuber
36. Quantifying the Contributions of Aerosol- and Snow-Produced ClNO2 through Observations and 1D Modeling D. Jeong et al.
37. Surface snow bromide and nitrate at Eureka, Canada, in early spring and implications for polar boundary layer chemistry X. Yang et al.
38. Reactive bromine in the low troposphere of Antarctica: estimations at two research sites C. Prados-Roman et al.
39. The Role of Snow in Controlling Halogen Chemistry and Boundary Layer Oxidation During Arctic Spring: A 1D Modeling Case Study S. Ahmed et al.
40. Investigation of processes controlling summertime gaseous elemental mercury oxidation at midlatitudinal marine, coastal, and inland sites Z. Ye et al.
41. Comparison of model and ground observations finds snowpack and blowing snow aerosols both contribute to Arctic tropospheric reactive bromine W. Swanson et al.
42. Modelling Arctic lower-tropospheric ozone: processes controlling seasonal variations W. Gong et al.
43. Air–snow exchange of nitrate: a modelling approach to investigate physicochemical processes in surface snow at Dome C, Antarctica J. Bock et al.
44. Bromide and chloride distribution across the snow‐sea ice‐ocean interface: A comparative study between an Arctic coastal marine site and an experimental sea ice mesocosm W. Xu et al.
45. Variability of bromine monoxide at Barrow, Alaska, over four halogen activation (March–May) seasons and at two on‐ice locations P. Peterson et al.
46. Low ozone dry deposition rates to sea ice during the MOSAiC field campaign: Implications for the Arctic boundary layer ozone budget J. Barten et al.
47. Iodine speciation in snow during the MOSAiC expedition and its implications for Arctic iodine emissions L. Brown et al.
48. Link Between Arctic Tropospheric BrO Explosion Observed From Space and Sea‐Salt Aerosols From Blowing Snow Investigated Using Ozone Monitoring Instrument BrO Data and GEOS‐5 Data Assimilation System S. Choi et al.
49. Seasonal bromate formation in the Arctic snowpack: Implications for the bromine biogeochemical cycle S. Frassati et al.
50. Updated trends for atmospheric mercury in the Arctic: 1995–2018 K. MacSween et al.
51. Production and Release of Molecular Bromine and Chlorine from the Arctic Coastal Snowpack K. Custard et al.
52. Observations of bromine monoxide transport in the Arctic sustained on aerosol particles P. Peterson et al.
53. Source mechanisms and transport patterns of tropospheric bromine monoxide: findings from long-term multi-axis differential optical absorption spectroscopy measurements at two Antarctic stations U. Frieß et al.
54. Fluxes of gaseous elemental mercury (GEM) in the High Arctic during atmospheric mercury depletion events (AMDEs) J. Kamp et al.
55. Polar oceans and sea ice in a changing climate M. Willis et al.
56. Photoreduction of mercuric bromides in polar ice J. Carmona-García et al.
57. Springtime Bromine Activation over Coastal and Inland Arctic Snowpacks P. Peterson et al.
58. Implications of Snowpack Reactive Bromine Production for Arctic Ice Core Bromine Preservation S. Zhai et al.