Publications

2023, Barten, J.G.M., et al., Low ozone dry deposition rates to sea ice during the MOSAiC field campaign: Implications for the Arctic boundary layer ozone budget, Elementa: Science of the Anthropocene, 11 (1): 00086, https://doi.org/10.1525/elementa.2022.00086
Tags: Arctic, Ozone, Sonde

2023, Whaley, C.H., Law, K. S., Hjorth, J. L., Skov, H., Arnold, S. R., Langner, J., Pernov, J. B., Bergeron, G., Bourgeois, I., Christensen, J. H., Chien, R.-Y., Deushi, M., Dong, X., Effertz, P., Faluvegi, G., Flanner, M., Fu, J. S., Gauss, M., Huey, G., Im, U., Kivi, R., Marelle, L., Onishi, T., Oshima, N., Petropavlovskikh, I., Peischl, J., Plummer, D. A., Pozzoli, L., Raut, J.-C., Ryerson, T., Skeie, R., Solberg, S., Thomas, M. A., Thompson, C., Tsigaridis, K., Tsyro, S., Turnock, S. T., von Salzen, K., and Tarasick, D. W., Paper 1: Arctic tropospheric ozone: assessment of current knowledge and model performance, Atmospheric Chemistry and Physics, 23, 637–661, https://doi.org/10.5194/acp-23-637-2023
Tags: Arctic, Ozone, Sonde, Tropospheric Ozone

2022, Bernhard, G.H., McKenzie, R.L., Lantz, K. et al., Updated analysis of data from Palmer Station, Antarctica (64° S), and San Diego, California (32° N), confirms large effect of the Antarctic ozone hole on UV radiation, Photochemical & Photobiological Sciences, 21, 373–384, https://doi.org/10.1007/s43630-022-00178-3
Tags: Ozone, Polar, Spectral UV, UVB

2022, Lei, L., Berkoff, T. A., Gronoff, G., Su, J., Nehrir, A. R., Wu, Y., ... & Kuang, S, Retrieval of UVB aerosol extinction profiles from the ground-based Langley Mobile Ozone Lidar (LMOL) system, Atmospheric Measurement Techniques, 5(8), 2465-2478
Tags: Aerosol, Lidar, Ozone, UVB

2022, McKenzie, R. , Liley, B., Kotkamp, M. et al., Relationship between ozone and biologically relevant UV at 4 NDACC sites, Photochemical & Photobiological Sciences, https://doi.org/10.1007/s43630-022-00281-5
Tags: Ozone, Spectral UV, UVB

2021, De Smedt, I., Pinardi, G., Vigouroux, C., Compernolle, S., Bais, A., Benavent, N., Boersma, F., Chan, K.-L., Donner, S., Eichmann, K.-U., Hedelt, P., Hendrick, F., Irie, H., Kumar, V., Lambert, J.-C., Langerock, B., Lerot, C., Liu, C., Loyola, D., Piters, A., Richter, A., Rivera Cárdenas, C., Romahn, F., Ryan, R. G., Sinha, V., Theys, N., Vlietinck, J., Wagner, T., Wang, T., Yu, H., and Van Roozendael, M, Comparative assessment of TROPOMI and OMI formaldehyde observations and validation against MAX-DOAS network column measurements, Atmospheric Chemistry and Physics, 21, 12561–12593, https://doi.org/10.5194/acp-21-12561-2021
Tags: CH2O, Satellite, UVVis

2021, Rivera Cárdenas, C., Guarín, C., Stremme, W., Friedrich, M. M., Bezanilla, A., Rivera Ramos, D., Mendoza-Rodríguez, C. A., Grutter, M., Blumenstock, T., Hase, F., Formaldehyde total column densities over Mexico City: comparison between multi-axis differential optical absorption spectroscopy and solar-absorption Fourier transform infrared measurements, Atmospheric Measurement Techniques, 14, 595–613, https://doi.org/10.5194/amt-14-595-2021
Tags: CH2O, FTIR

2021, Tu, Q., Hase, F., Blumenstock, T., Schneider, M., Schneider, A., Kivi, R., Heikkinen, P., Ertl, B., Diekmann, C., Khosrawi, F., Sommer, M., Borsdorff, T., and Raffalski, U., Intercomparison of arctic XH2O observations from three ground-based Fourier transform infrared networks and application for satellite validation, Atmospheric Measurement Techniques, 14, 1993–2011, https://doi.org/10.5194/amt-14-1993-2021
Tags: FTIR, Arctic, XH2O, Satellite

2021, von der Gathen, P., Kivi, R., Wohltmann, I. et al., Climate change favours large seasonal loss of Arctic ozone, Nature Communications, 725708, https://doi.org/10.1038/s41467-021-24089-6
Tags: Arctic, Ozone

2020, Becagli, S., Caiazzo L., Di Iorio Tatiana, Di Sarra Alcide, Meloni Daniela, Muscari G., Pace G., Severi M., and Traversi R., New insights on metals in the Arctic aerosol in a climate changing world, Science of the Total Environment, 741, https://doi.org/10.1016/j.scitotenv.2020.140511
Tags: Aerosol, Arctic, Lidar