Your search keyword '"Kreher, K"' showing total 15 results

1. Intercomparison of NO2, O4, O3 and HCHO slant column measurements by MAX-DOAS and zenith-sky UV-visible spectrometers during CINDI-2

Author

Kreher, K., Roozendael, M. van, Hendrick, F., Apituley, A., Dimitropoulou, E., Friess, U., Richter, A., Wagner, T., Lampel, J., Abuhassan, N., Ang, L., Anguas, M., Bais, A., Benavent, N., Bosch, T., Bognar, K., Borovski, A., Bruchkouski, I., Cede, A., Chan, K. lok, Donner, S., Drosoglou, T., Fayt, C., Finkenzeller, H., Garcia-Nieto, D., Gielen, C., Gómez-Martín, L., Hao, N., Henzing, B., Herman, J., Hermans, C., Hoque, S., Irie, H., Jin, J., Johnston, P., Butt, J. khayyam, Khokhar, F., Koenig, T., Kuhn, J., Kumar, V., Liu, C., Ma, J., Merlaud, A., Mishra, A., Müller, M., Navarro-Comas, M., Ostendorf, M., Pazmino, A., Peters, E., Pinardi, G., Pinharanda, M., Piters, A., Platt, U., Postylyakov, O., Prados-Roman, C., Puentedura, O., Querel, R., Saiz-Lopez, A., Schonhardt, A., Schreier, S., Sinha, V., Spinei, E., Strong, K., Tack, F., Tian, X., Tiefengraber, M., Gent, J. van, Volkamer, R., Vrekoussis, M., Wang, S., Wang, Z., Wenig, M., Wittrock, F., Xie, P., Xu, J., Yela, M., Zhang, C., and Zhao, X.

Subjects

Data set, Satellite data, Measurement method, Air mass, Urbanisation, Environment & Sustainability, Instrumentation, Spectrometer

Abstract

In September 2016, 36 spectrometers from 24 institutes measured a number of key atmospheric pollutants for a period of 17 d during the Second Cabauw Intercomparison campaign for Nitrogen Dioxide measuring Instruments (CINDI-2) that took place at Cabauw, the Netherlands (51.97-N, 4.93-E). We report on the outcome of the formal semi-blind intercomparison exercise, which was held under the umbrella of the Network for the Detection of Atmospheric Composition Change (NDACC) and the European Space Agency (ESA). The three major goals of CINDI-2 were (1) to characterise and better understand the differences between a large number of multi-axis differential optical absorption spectroscopy (MAX-DOAS) and zenith-sky DOAS instruments and analysis methods, (2) to define a robust methodology for performance assessment of all participating instruments, and (3) to contribute to a harmonisation of the measurement settings and retrieval methods. This, in turn, creates the capability to produce consistent high-quality ground-based data sets, which are an essential requirement to generate reliable long-term measurement time series suitable for trend analysis and satellite data validation. The data products investigated during the semi-blind intercomparison are slant columns of nitrogen dioxide (NO2), the oxygen collision complex (O4) and ozone (O3) measured in the UV and visible wavelength region, formaldehyde (HCHO) in the UV spectral region, and NO2 in an additional (smaller) wavelength range in the visible region. The campaign design and implementation processes are discussed in detail including the measurement protocol, calibration procedures and slant column retrieval settings. Strong emphasis was put on the careful alignment and synchronisation of the measurement systems, resulting in a unique set of measurements made under highly comparable air mass conditions. The CINDI-2 data sets were investigated using a regression analysis of the slant columns measured by each instrument and for each of the target data products. The slope and intercept of the regression analysis respectively quantify the mean systematic bias and offset of the individual data sets against the selected reference (which is obtained from the median of either all data sets or a subset), and the rms error provides an estimate of the measurement noise or dispersion. These three criteria are examined and for each of the parameters and each of the data products, performance thresholds are set and applied to all the measurements. The approach presented here has been developed based on heritage from previous intercomparison exercises. It introduces a quantitative assessment of the consistency between all the participating instruments for the MAX-DOAS and zenith-sky DOAS techniques. ©Author(s) 2020. This work is distributed under the Creative Commons Attribution 4.0 License.

Published

2020

2. Boundary layer new particle formation over East Antarctic sea ice - Possible Hg driven nucleation?

Author

Humphries, RS, Schofield, R, Keywood, M, Ward, J, Pierce, JR, Gionfriddo, CM, Tate, M, Krabbenhoft, D, Galbally, IE, Molloy, SB, Klekociuk, A, Johnston, PV, Kreher, K, Thomas, AJ, Robinson, AD, Harris, NRP, Johnson, R, Wilson, SR, Humphries, RS, Schofield, R, Keywood, M, Ward, J, Pierce, JR, Gionfriddo, CM, Tate, M, Krabbenhoft, D, Galbally, IE, Molloy, SB, Klekociuk, A, Johnston, PV, Kreher, K, Thomas, AJ, Robinson, AD, Harris, NRP, Johnson, R, and Wilson, SR

Abstract

Aerosol observations above the Southern Ocean and Antarctic sea ice are scarce. Measurements of aerosols and atmospheric composition were made in East Antarctic pack ice on-board the Australian icebreaker Aurora Australis during the spring of 2012. One particle formation event was observed during the 32 days of observations. This event occurred on the only day to exhibit extended periods of global irradiance in excess of 600 W m−2. Within the single air-mass influencing the measurements, number concentrations of particles larger than 3 nm (CN3) reached almost 7700 cm−3 within a few hours of clouds clearing, and grew at rates of 5.6 nm h−1. Formation rates of 3 nm particles were in the range of those measured at other Antarctic locations at 0.2–1.1 ± 0.1 cm−3 s−1. Our investigations into the nucleation chemistry found that there were insufficient precursor concentrations for known halogen or organic chemistry to explain the nucleation event. Modelling studies utilising known sulfuric acid nucleation schemes could not simultaneously reproduce both particle formation or growth rates. Surprising correlations with Total Gaseous Mercury (TGM) were found that, together with other data, suggest a mercury driven photochemical nucleation mechanism may be responsible for aerosol nucleation. Given the very low vapour pressures of the mercury species involved, this nucleation chemistry is likely only possible where pre-existing aerosol concentrations are low and both TGM concentrations and solar radiation levels are relatively high (~ 1.5 ng m−3 and ≥ 600 W m−2, respectively), such as those observed in the Antarctic sea ice boundary layer in this study or in the global free-troposphere, particularly in the Northern Hemisphere.

Published

2015

3. Boundary layer new particle formation over East Antarctic sea ice – possible Hg-driven nucleation?

Author

Humphries, R. S., primary, Schofield, R., additional, Keywood, M. D., additional, Ward, J., additional, Pierce, J. R., additional, Gionfriddo, C. M., additional, Tate, M. T., additional, Krabbenhoft, D. P., additional, Galbally, I. E., additional, Molloy, S. B., additional, Klekociuk, A. R., additional, Johnston, P. V., additional, Kreher, K., additional, Thomas, A. J., additional, Robinson, A. D., additional, Harris, N. R. P., additional, Johnson, R., additional, and Wilson, S. R., additional

Published

2015

4. An objective determination of optimal site locations for detecting expected trends in upper-air temperature and total column ozone

Author

Kreher, K., primary, Bodeker, G. E., additional, and Sigmond, M., additional

Published

2015

5. Analysis of stratospheric NO<sub>2</sub> trends above Jungfraujoch using ground-based UV-visible, FTIR, and satellite nadir observations

Author

Hendrick, F., primary, Mahieu, E., additional, Bodeker, G. E., additional, Boersma, K. F., additional, Chipperfield, M. P., additional, De Mazière, M., additional, De Smedt, I., additional, Demoulin, P., additional, Fayt, C., additional, Hermans, C., additional, Kreher, K., additional, Lejeune, B., additional, Pinardi, G., additional, Servais, C., additional, Stübi, R., additional, van der A, R., additional, Vernier, J.-P., additional, and Van Roozendael, M., additional

Published

2012

6. Impact of meteorological analyses and chemical data assimilation on modelled long-term changes in stratospheric NO2

Author

Gunn, L. N., primary, Chipperfield, M. P., additional, Feng, W., additional, Van Roozendael, M., additional, Gil, M., additional, Yela, M., additional, Johnston, P. V., additional, Kreher, K., additional, and Wood, S. W., additional

Published

2012

7. The Cabauw Intercomparison campaign for Nitrogen Dioxide measuring Instruments (CINDI): design, execution, and early results

Author

Piters, A. J. M., primary, Boersma, K. F., additional, Kroon, M., additional, Hains, J. C., additional, Van Roozendael, M., additional, Wittrock, F., additional, Abuhassan, N., additional, Adams, C., additional, Akrami, M., additional, Allaart, M. A. F., additional, Apituley, A., additional, Beirle, S., additional, Bergwerff, J. B., additional, Berkhout, A. J. C., additional, Brunner, D., additional, Cede, A., additional, Chong, J., additional, Clémer, K., additional, Fayt, C., additional, Frieß, U., additional, Gast, L. F. L., additional, Gil-Ojeda, M., additional, Goutail, F., additional, Graves, R., additional, Griesfeller, A., additional, Großmann, K., additional, Hemerijckx, G., additional, Hendrick, F., additional, Henzing, B., additional, Herman, J., additional, Hermans, C., additional, Hoexum, M., additional, van der Hoff, G. R., additional, Irie, H., additional, Johnston, P. V., additional, Kanaya, Y., additional, Kim, Y. J., additional, Klein Baltink, H., additional, Kreher, K., additional, de Leeuw, G., additional, Leigh, R., additional, Merlaud, A., additional, Moerman, M. M., additional, Monks, P. S., additional, Mount, G. H., additional, Navarro-Comas, M., additional, Oetjen, H., additional, Pazmino, A., additional, Perez-Camacho, M., additional, Peters, E., additional, du Piesanie, A., additional, Pinardi, G., additional, Puentedura, O., additional, Richter, A., additional, Roscoe, H. K., additional, Schönhardt, A., additional, Schwarzenbach, B., additional, Shaiganfar, R., additional, Sluis, W., additional, Spinei, E., additional, Stolk, A. P., additional, Strong, K., additional, Swart, D. P. J., additional, Takashima, H., additional, Vlemmix, T., additional, Vrekoussis, M., additional, Wagner, T., additional, Whyte, C., additional, Wilson, K. M., additional, Yela, M., additional, Yilmaz, S., additional, Zieger, P., additional, and Zhou, Y., additional

Published

2012

8. The Cabauw Intercomparison campaign for Nitrogen Dioxide measuring Instruments (CINDI): design, execution, and early results

Author

Piters, A. J. M., primary, Boersma, K. F., additional, Kroon, M., additional, Hains, J. C., additional, Van Roozendael, M., additional, Wittrock, F., additional, Abuhassan, N., additional, Adams, C., additional, Akrami, M., additional, Allaart, M. A. F., additional, Apituley, A., additional, Bergwerff, J. B., additional, Berkhout, A. J. C., additional, Brunner, D., additional, Cede, A., additional, Chong, J., additional, Clémer, K., additional, Fayt, C., additional, Frieß, U., additional, Gast, L. F. L., additional, Gil-Ojeda, M., additional, Goutail, F., additional, Graves, R., additional, Griesfeller, A., additional, Großmann, K., additional, Hemerijckx, G., additional, Hendrick, F., additional, Henzing, B., additional, Herman, J., additional, Hermans, C., additional, Hoexum, M., additional, van der Hoff, G. R., additional, Irie, H., additional, Johnston, P. V., additional, Kanaya, Y., additional, Kim, Y. J., additional, Klein Baltink, H., additional, Kreher, K., additional, de Leeuw, G., additional, Leigh, R., additional, Merlaud, A., additional, Moerman, M. M., additional, Monks, P. S., additional, Mount, G. H., additional, Navarro-Comas, M., additional, Oetjen, H., additional, Pazmino, A., additional, Perez-Camacho, M., additional, Peters, E., additional, du Piesanie, A., additional, Pinardi, G., additional, Puentadura, O., additional, Richter, A., additional, Roscoe, H. K., additional, Schönhardt, A., additional, Schwarzenbach, B., additional, Shaiganfar, R., additional, Sluis, W., additional, Spinei, E., additional, Stolk, A. P., additional, Strong, K., additional, Swart, D. P. J., additional, Takashima, H., additional, Vlemmix, T., additional, Vrekoussis, M., additional, Wagner, T., additional, Whyte, C., additional, Wilson, K. M., additional, Yela, M., additional, Yilmaz, S., additional, Zieger, P., additional, and Zhou, Y., additional

Published

2011

9. Global observations of tropospheric BrO columns using GOME-2 satellite data

Author

Theys, N., primary, Van Roozendael, M., additional, Hendrick, F., additional, Yang, X., additional, De Smedt, I., additional, Richter, A., additional, Begoin, M., additional, Errera, Q., additional, Johnston, P. V., additional, Kreher, K., additional, and De Mazière, M., additional

Published

2011

10. Intercomparison of slant column measurements of NO<sub>2</sub> and O<sub>4</sub> by MAX-DOAS and zenith-sky UV and visible spectrometers

Author

Roscoe, H. K., primary, Van Roozendael, M., additional, Fayt, C., additional, du Piesanie, A., additional, Abuhassan, N., additional, Adams, C., additional, Akrami, M., additional, Cede, A., additional, Chong, J., additional, Clémer, K., additional, Friess, U., additional, Gil Ojeda, M., additional, Goutail, F., additional, Graves, R., additional, Griesfeller, A., additional, Grossmann, K., additional, Hemerijckx, G., additional, Hendrick, F., additional, Herman, J., additional, Hermans, C., additional, Irie, H., additional, Johnston, P. V., additional, Kanaya, Y., additional, Kreher, K., additional, Leigh, R., additional, Merlaud, A., additional, Mount, G. H., additional, Navarro, M., additional, Oetjen, H., additional, Pazmino, A., additional, Perez-Camacho, M., additional, Peters, E., additional, Pinardi, G., additional, Puentedura, O., additional, Richter, A., additional, Schönhardt, A., additional, Shaiganfar, R., additional, Spinei, E., additional, Strong, K., additional, Takashima, H., additional, Vlemmix, T., additional, Vrekoussis, M., additional, Wagner, T., additional, Wittrock, F., additional, Yela, M., additional, Yilmaz, S., additional, Boersma, F., additional, Hains, J., additional, Kroon, M., additional, Piters, A., additional, and Kim, Y. J., additional

Published

2010

11. Global observations of tropospheric BrO columns using GOME-2 satellite data

Author

Theys, N., primary, Van Roozendael, M., additional, Hendrick, F., additional, Yang, X., additional, De Smedt, I., additional, Richter, A., additional, Begoin, M., additional, Errera, Q., additional, Johnston, P. V., additional, Kreher, K., additional, and De Mazière, M., additional

Published

2010

12. Multi-year comparison of stratospheric BrO vertical profiles retrieved from SCIAMACHY limb and ground-based UV-visible measurements

Author

Hendrick, F., primary, Rozanov, A., additional, Johnston, P. V., additional, Bovensmann, H., additional, De Mazière, M., additional, Fayt, C., additional, Hermans, C., additional, Kreher, K., additional, Lotz, W., additional, Sinnhuber, B.-M., additional, Theys, N., additional, Thomas, A., additional, Burrows, J. P., additional, and Van Roozendael, M., additional

Published

2009

13. Multi-year comparison of stratospheric BrO vertical profiles retrieved from SCIAMACHY limb and ground-based UV-visible measurements

Author

Hendrick, F., primary, Rozanov, A., additional, Johnston, P. V., additional, Bovensmann, H., additional, De Mazière, M., additional, Fayt, C., additional, Hermans, C., additional, Kreher, K., additional, Lotz, W., additional, Sinnhuber, B.-M., additional, Theys, N., additional, Thomas, A., additional, Burrows, J. P., additional, and Van Roozendael, M., additional

Published

2008

14. Past and future simulations of NO2 from a coupled chemistry-climate model in comparison with observations

Author

Struthers, H., primary, Kreher, K., additional, Austin, J., additional, Schofield, R., additional, Bodeker, G., additional, Johnston, P., additional, Shiona, H., additional, and Thomas, A., additional

Published

2004

15. MAX-DOAS measurements of atmospheric rural and urban NO2 gradients during the TROLIX'19 campaign

Author

Karin Kreher, Elena Spinei, Ankie Piters, Arnoud Apituley, Alkis Bais, Steffen Doerner, Caroline Fayt, Martina Friedrich, Arnoud Frumau, Francois Hendrick, Christian Hermans, Dimitris Karagkiozidis, Richard Querel, Michel Van Roozendael, Jan Vonk, and Thomas Wagner

Abstract

As part of the TROLIX'19 (TROpomi vaLIdation eXperiment) campaign (2 September to 4 October 2019), measurements of tropospheric NO2 columns and surface concentrations were made using the MAX-DOAS (Multi-AXis Differential Optical Absorption Spectroscopy) technique. To characterise any TROPOMI sub pixel (less than 3.5 km x 7 km) heterogeneity, four MAX-DOAS instruments were deployed at rural locations close to Cabauw (51.97°N, 4.93°E) and further six instruments were operated within the highly industrialized area of Rotterdam (51.92°N, 4.48°E) in the Netherlands. All instruments performed sky scanning from the horizon (from approximately 1°) to the zenith. In addition, two of the MAX-DOAS instruments (Pandoras) also measured total NO2 columns in direct sun mode.Here we present first results focusing on the measurements of NO2 spatial gradients made at sites within approximately 3-10 km distance in a rural and an urban environment. The data analysis was done in two steps. Differential slant column densities were calculated using the data processing procedures established during the CINDI-2 intercomparison campaign (Kreher et al., in review, 2019) in UV and VIS spectral ranges. Tropospheric columns, near surface concentrations and profiles were then calculated using the Pandora real time algorithm as well as the NDACC UV-Vis Central Processing system developed in the ESA FRM4DOAS project. Local heterogeneity at the surface level was evaluated using in-situ NO2 measurements available from several routine monitoring stations within the area of interest. The local NO2 heterogeneity effect on TROPOMI validation is also discussed.Reference:Kreher, K. et al.: Intercomparison of NO2, O4, O3 and HCHO slant column measurements by MAX-DOAS and zenith-sky UV-Visible spectrometers during the CINDI-2 campaign, Atmos. Meas. Tech. Discuss., https://doi.org/10.5194/amt-2019-157, in review, 2019.

Published

2020