Your search keyword '"Pettit, J. M."' showing total 14 results

1. The Relationship Between Electron Precipitation and the Population of Trapped Electrons in LEO: New Evidence Supporting a Natural Limit to the Flux of Energetic Electrons

Author

Ozeke, L. G., primary, Mann, I. R., additional, Olifer, L., additional, Chakraborty, S., additional, and Pettit, J. M., additional

Published

2024

2. Electron Lifetimes Measured at LEO: Comparison With RBSP Estimates and Pitch Angle Resolved Lifetimes

Author

Shane, A. D., primary, Marshall, R. A., additional, Claudepierre, S. G., additional, and Pettit, J. M., additional

Published

2023

3. Quantifying the Size and Duration of a Microburst‐Producing Chorus Region on 5 December 2017

Author

Elliott, S. S., primary, Breneman, A. W., additional, Colpitts, C., additional, Pettit, J. M., additional, Cattell, C. A., additional, Halford, A. J., additional, Shumko, M., additional, Sample, J., additional, Johnson, A. T., additional, Miyoshi, Y., additional, Kasahara, Y., additional, Cully, C. M., additional, Nakamura, S., additional, Mitani, T., additional, Hori, T., additional, Shinohara, I., additional, Shiokawa, K., additional, Matsuda, S., additional, Connors, M., additional, Ozaki, M., additional, and Manninen, J., additional

Published

2022

4. Heppa III Intercomparison Experiment on Electron Precipitation Impacts : 2. Model-Measurement Intercomparison of Nitric Oxide (NO) During a Geomagnetic Storm in April 2010

Author

Sinnhuber, M., Nesse Tyssøy, H., Asikainen, T., Bender, S., Funke, B., Hendrickx, Koen, Pettit, J. M., Reddmann, T., Rozanov, E., Schmidt, H., Smith-Johnsen, C., Sukhodolov, T., Szelag, M. E., van de Kamp, M., Verronen, P. T., Wissing, J. M., Yakovchuk, O. S., Sinnhuber, M., Nesse Tyssøy, H., Asikainen, T., Bender, S., Funke, B., Hendrickx, Koen, Pettit, J. M., Reddmann, T., Rozanov, E., Schmidt, H., Smith-Johnsen, C., Sukhodolov, T., Szelag, M. E., van de Kamp, M., Verronen, P. T., Wissing, J. M., and Yakovchuk, O. S.

Abstract

Precipitating auroral and radiation belt electrons are considered to play an important part in the natural forcing of the middle atmosphere with a possible impact on the climate system. Recent studies suggest that this forcing is underestimated in current chemistry-climate models. The HEPPA III intercomparison experiment is a collective effort to address this point. In this study, we apply electron ionization rates from three data-sets in four chemistry-climate models during a geomagnetically active period in April 2010. Results are evaluated by comparison with observations of nitric oxide (NO) in the mesosphere and lower thermosphere. Differences between the ionization rate data-sets have been assessed in a companion study. In the lower thermosphere, NO densities differ by up to one order of magnitude between models using the same ionization rate data-sets due to differences in the treatment of NO formation, model climatology, and model top height. However, a good agreement in the spatial and temporal variability of NO with observations lends confidence that the electron ionization is represented well above 80 km. In the mesosphere, the averages of model results from all chemistry-climate models differ consistently with the differences in the ionization-rate data-sets, but are within the spread of the observations, so no clear assessment on their comparative validity can be provided. However, observed enhanced amounts of NO in the mid-mesosphere below 70 km suggest a relevant contribution of the high-energy tail of the electron distribution to the hemispheric NO budget during and after the geomagnetic storm on April 6.

Published

2022

5. Quantifying the size and duration of a microburst-producing chorus region on 5 December 2017

Author

Elliott, S. S. (S. S.), Breneman, A. W. (A. W.), Colpitts, C. (C.), Pettit, J. M. (J. M.), Cattell, C. A. (C. A.), Halford, A. J. (A. J.), Shumko, M. (M.), Sample, J. (J.), Johnson, A. T. (A. T.), Miyoshi, Y. (Y.), Kasahara, Y. (Y.), Cully, C. M. (C. M.), Nakamura, S. (S.), Mitani, T. (T.), Hori, T. (T.), Shinohara, I. (I.), Shiokawa, K. (K.), Matsuda, S. (S.), Connors, M. (M.), Ozaki, M. (M.), and Manninen, J. (J.)

Subjects

electron precipitation, chorus waves, microburst precipitation, radiation belt, wave-particle interactions

Abstract

Microbursts are impulsive (30 keV) precipitation (FIREBIRD II and AC6 CubeSats, POES) to determine the size of the microburst-producing chorus source region beginning on 5 December 2017. We estimate that the long-lasting (∼30 hr) microburst-producing chorus region extends from 4 to 8 ΔMLT and 2–5 ΔL. We conclude that microbursts likely represent a major loss source of outer radiation belt electrons for this event.

Published

2022

6. Heppa III Intercomparison Experiment on Electron Precipitation Impacts: 2. Model‐Measurement Intercomparison of Nitric Oxide (NO) During a Geomagnetic Storm in April 2010

Author

Sinnhuber, M., primary, Nesse Tyssøy, H., additional, Asikainen, T., additional, Bender, S., additional, Funke, B., additional, Hendrickx, K., additional, Pettit, J. M., additional, Reddmann, T., additional, Rozanov, E., additional, Schmidt, H., additional, Smith‐Johnsen, C., additional, Sukhodolov, T., additional, Szeląg, M. E., additional, van de Kamp, M., additional, Verronen, P. T., additional, Wissing, J. M., additional, and Yakovchuk, O. S., additional

Published

2021

7. HEPPA III Intercomparison Experiment on Electron Precipitation Impacts: 1. Estimated Ionization Rates During a Geomagnetic Active Period in April 2010

Author

Nesse Tyssøy, H., primary, Sinnhuber, M., additional, Asikainen, T., additional, Bender, S., additional, Clilverd, M. A., additional, Funke, B., additional, van de Kamp, M., additional, Pettit, J. M., additional, Randall, C. E., additional, Reddmann, T., additional, Rodger, C. J., additional, Rozanov, E., additional, Smith‐Johnsen, C., additional, Sukhodolov, T., additional, Verronen, P. T., additional, Wissing, J. M., additional, and Yakovchuk, O., additional

Published

2021

8. Heppa III intercomparison experiment on electron precipitation impacts:2. model-measurement intercomparison of nitric oxide (NO) during a geomagnetic storm in April 2010

Author

Sinnhuber, M. (M.), Nesse Tyssøy, H. (H.), Asikainen, T. (T.), Bender, S. (S.), Funke, B. (B.), Hendrickx, K. (K.), Pettit, J. M. (J. M.), Reddmann, T. (T.), Rozanov, E. (E.), Schmidt, H. (H.), Smith-Johnsen, C. (C.), Sukhodolov, T. (T.), Szeląg, M. E. (M. E.), van de Kamp, M. (M.), Verronen, P. T. (P. T.), Wissing, J. M. (J. M.), Yakovchuk, O. S. (O. S.), Sinnhuber, M. (M.), Nesse Tyssøy, H. (H.), Asikainen, T. (T.), Bender, S. (S.), Funke, B. (B.), Hendrickx, K. (K.), Pettit, J. M. (J. M.), Reddmann, T. (T.), Rozanov, E. (E.), Schmidt, H. (H.), Smith-Johnsen, C. (C.), Sukhodolov, T. (T.), Szeląg, M. E. (M. E.), van de Kamp, M. (M.), Verronen, P. T. (P. T.), Wissing, J. M. (J. M.), and Yakovchuk, O. S. (O. S.)

Abstract

Precipitating auroral and radiation belt electrons are considered to play an important part in the natural forcing of the middle atmosphere with a possible impact on the climate system. Recent studies suggest that this forcing is underestimated in current chemistry-climate models. The HEPPA III intercomparison experiment is a collective effort to address this point. In this study, we apply electron ionization rates from three data-sets in four chemistry-climate models during a geomagnetically active period in April 2010. Results are evaluated by comparison with observations of nitric oxide (NO) in the mesosphere and lower thermosphere. Differences between the ionization rate data-sets have been assessed in a companion study. In the lower thermosphere, NO densities differ by up to one order of magnitude between models using the same ionization rate data-sets due to differences in the treatment of NO formation, model climatology, and model top height. However, a good agreement in the spatial and temporal variability of NO with observations lends confidence that the electron ionization is represented well above 80 km. In the mesosphere, the averages of model results from all chemistry-climate models differ consistently with the differences in the ionization-rate data-sets, but are within the spread of the observations, so no clear assessment on their comparative validity can be provided. However, observed enhanced amounts of NO in the mid-mesosphere below 70 km suggest a relevant contribution of the high-energy tail of the electron distribution to the hemispheric NO budget during and after the geomagnetic storm on April 6.

Published

2021

9. HEPPA III intercomparison experiment on electron precipitation impacts:1. estimated ionization rates during a geomagnetic active period in April 2010

Author

Nesse Tyssøy, H. (H.), Sinnhuber, M. (M.), Asikainen, T. (T.), Bender, S. (S.), Clilverd, M. A. (M. A.), Funke, B. (B.), van de Kamp, M. (M.), Pettit, J. M. (J. M.), Randall, C. E. (C. E.), Reddmann, T. (T.), Rodger, C. J. (C. J.), Rozanov, E. (E.), Smith-Johnsen, C. (C.), Sukhodolov, T. (T.), Verronen, P. T. (P. T.), Wissing, J. M. (J. M.), Yakovchuk, O. (O.), Nesse Tyssøy, H. (H.), Sinnhuber, M. (M.), Asikainen, T. (T.), Bender, S. (S.), Clilverd, M. A. (M. A.), Funke, B. (B.), van de Kamp, M. (M.), Pettit, J. M. (J. M.), Randall, C. E. (C. E.), Reddmann, T. (T.), Rodger, C. J. (C. J.), Rozanov, E. (E.), Smith-Johnsen, C. (C.), Sukhodolov, T. (T.), Verronen, P. T. (P. T.), Wissing, J. M. (J. M.), and Yakovchuk, O. (O.)

Abstract

Precipitating auroral and radiation belt electrons are considered an important part of the natural forcing of the climate system. Recent studies suggest that this forcing is underestimated in current chemistry-climate models. The High Energy Particle Precipitation in the Atmosphere III intercomparison experiment is a collective effort to address this point. Here, eight different estimates of medium energy electron (MEE) (gt; 30 kev) ionization rates are assessed during a geomagnetic active period in April 2010. The objective is to understand the potential uncertainty related to the MEE energy input. The ionization rates are all based on the Medium Energy Proton and Electron Detector (MEPED) on board the NOAA/POES and EUMETSAT/MetOp spacecraft series. However, different data handling, ionization rate calculations, and background atmospheres result in a wide range of mesospheric electron ionization rates. Although the eight data sets agree well in terms of the temporal variability, they differ by about an order of magnitude in ionization rate strength both during geomagnetic quiet and disturbed periods. The largest spread is found in the aftermath of enhanced geomagnetic activity. Furthermore, governed by different energy limits, the atmospheric penetration depth varies, and some differences related to latitudinal coverage are also evident. The mesospheric NO densities simulated with the Whole Atmospheric Community Climate Model driven by highest and lowest ionization rates differ by more than a factor of eight. In a follow-up study, the atmospheric responses are simulated in four chemistry-climate models (CCM) and compared to satellite observations, considering both the CCM structure and the ionization forcing.

Published

2021

10. Both Cyclone‐induced and Convective Storms Drive Disturbance Patterns in European Primary Beech Forests

Author

Pettit, J. L., primary, Pettit, J. M., additional, Janda, P., additional, Rydval, M., additional, Čada, V., additional, Schurman, J. S., additional, Nagel, T. A., additional, Bače, R., additional, Saulnier, M., additional, Hofmeister, J., additional, Matula, R., additional, Kozák, D., additional, Frankovič, M., additional, Turcu, D. O., additional, Mikoláš, M., additional, and Svoboda, M., additional

Published

2021

11. HEPPA III Intercomparison Experiment on Electron Precipitation Impacts: 1. Estimated Ionization Rates During a Geomagnetic Active Period in April 2010.

Author

Tyssøy, H. Nesse, Sinnhuber, M., Asikainen, T., Bender, S., Clilverd, M. A., Funke, B., van de Kamp, M., Pettit, J. M., Randall, C. E., Reddmann, T., Rodger, C. J., Rozanov, E., Smith-Johnsen, C., Sukhodolov, T., Verronen, P. T., Wissing, J. M., and Yakovchuk, O.

Subjects

ELECTRON precipitation, VAN Allen radiation belts, MAGNETOSPHERE, GEOMAGNETISM, ELECTRON impact ionization

Abstract

Precipitating auroral and radiation belt electrons are considered an important part of the natural forcing of the climate system. Recent studies suggest that this forcing is underestimated in current chemistryclimate models. The High Energy Particle Precipitation in the Atmosphere III intercomparison experiment is a collective effort to address this point. Here, eight different estimates of medium energy electron (MEE) (>30 keV) ionization rates are assessed during a geomagnetic active period in April 2010. The objective is to understand the potential uncertainty related to the MEE energy input. The ionization rates are all based on the Medium Energy Proton and Electron Detector (MEPED) on board the NOAA/POES and EUMETSAT/MetOp spacecraft series. However, different data handling, ionization rate calculations, and background atmospheres result in a wide range of mesospheric electron ionization rates. Although the eight data sets agree well in terms of the temporal variability, they differ by about an order of magnitude in ionization rate strength both during geomagnetic quiet and disturbed periods. The largest spread is found in the aftermath of enhanced geomagnetic activity. Furthermore, governed by different energy limits, the atmospheric penetration depth varies, and some differences related to latitudinal coverage are also evident. The mesospheric NO densities simulated with the Whole Atmospheric Community Climate Model driven by highest and lowest ionization rates differ by more than a factor of eight. In a follow-up study, the atmospheric responses are simulated in four chemistry-climate models (CCM) and compared to satellite observations, considering both the CCM structure and the ionization forcing. [ABSTRACT FROM AUTHOR]

Published

2022

12. Atmospheric Effects of >30‐keV Energetic Electron Precipitation in the Southern Hemisphere Winter During 2003

Author

Pettit, J. M., primary, Randall, C. E., additional, Peck, E. D., additional, Marsh, D. R., additional, van de Kamp, M., additional, Fang, X., additional, Harvey, V. L., additional, Rodger, C. J., additional, and Funke, B., additional

Published

2019

13. HEPPA III Intercomparison Experiment on Electron Precipitation Impacts: 1. Estimated Ionization Rates During a Geomagnetic Active Period in April 2010

Author

Nesse Tyssøy, H., Sinnhuber, M., Asikainen, T., Bender, S., Clilverd, M. A., Funke, B., Kamp, M., Pettit, J. M., Randall, C. E., Reddmann, T., Rodger, C. J., Rozanov, E., Smith‐Johnsen, C., Sukhodolov, T., Verronen, P. T., Wissing, J. M., and Yakovchuk, O.

Abstract

Precipitating auroral and radiation belt electrons are considered an important part of the natural forcing of the climate system. Recent studies suggest that this forcing is underestimated in current chemistry‐climate models. The High Energy Particle Precipitation in the Atmosphere III intercomparison experiment is a collective effort to address this point. Here, eight different estimates of medium energy electron (MEE) (>30keV)$(> 30\hspace*{.5em}keV)$ionization rates are assessed during a geomagnetic active period in April 2010. The objective is to understand the potential uncertainty related to the MEE energy input. The ionization rates are all based on the Medium Energy Proton and Electron Detector (MEPED) on board the NOAA/POES and EUMETSAT/MetOp spacecraft series. However, different data handling, ionization rate calculations, and background atmospheres result in a wide range of mesospheric electron ionization rates. Although the eight data sets agree well in terms of the temporal variability, they differ by about an order of magnitude in ionization rate strength both during geomagnetic quiet and disturbed periods. The largest spread is found in the aftermath of enhanced geomagnetic activity. Furthermore, governed by different energy limits, the atmospheric penetration depth varies, and some differences related to latitudinal coverage are also evident. The mesospheric NO densities simulated with the Whole Atmospheric Community Climate Model driven by highest and lowest ionization rates differ by more than a factor of eight. In a follow‐up study, the atmospheric responses are simulated in four chemistry‐climate models (CCM) and compared to satellite observations, considering both the CCM structure and the ionization forcing. Eight different electron ionization rates based on POES Medium Energy Proton and Electron Detector are comparedDifferences of up to one order of magnitude between the highest and lowest ionization rates are foundThe modeled response to the electron ionization rates varies by about a factor of eight in mesospheric NO density Eight different electron ionization rates based on POES Medium Energy Proton and Electron Detector are compared Differences of up to one order of magnitude between the highest and lowest ionization rates are found The modeled response to the electron ionization rates varies by about a factor of eight in mesospheric NO density

Published

2022

14. Heppa III Intercomparison Experiment on Electron Precipitation Impacts: 2. Model-Measurement Intercomparison of Nitric Oxide (NO) During a Geomagnetic Storm in April 2010

Author

M. Sinnhuber, H. Nesse Tyssøy, T. Asikainen, S. Bender, B. Funke, K. Hendrickx, J. M. Pettit, T. Reddmann, E. Rozanov, H. Schmidt, C. Smith‐Johnsen, T. Sukhodolov, M. E. Szeląg, M. van de Kamp, P. T. Verronen, J. M. Wissing, O. S. Yakovchuk, Ministerio de Ciencia e Innovación (España), European Commission, Nesse Tyssøy, H., 2 Department Physics and Technology Birkeland Centre for Space Science University of Bergen Bergen Norway, Asikainen, T., 3 University of Oulu Oulu Finland, Bender, S., 4 Norwegian University of Science and Technology Trondheim Norway, Funke, B., 5 Instituto de Astrofísica de Andalucía CSIC Granada Spain, Hendrickx, K., 6 Formerly at the Department of Meteorology Stockholm University Stockholm Sweden, Pettit, J. M., 7 LASP University of Colorado Boulder CO USA, Reddmann, T., 1 Karlsruhe Institute of Technology Leopoldshafen Germany, Rozanov, E., 8 PMOD/WRC Davos and IAC ETH Zurich Switzerland, Schmidt, H., 10 Max‐Planck Institute for Meteorologie Hamburg Germany, Smith‐Johnsen, C., Sukhodolov, T., Szeląg, M. E., 12 Space and Earth Observation Centre Finnish Meteorological Institute Helsinki Finland, van de Kamp, M., Verronen, P. T., Wissing, J. M., 13 University of Rostock Rostock Germany, Yakovchuk, O. S., and 9 Saint Petersburg State University Saint Petersburg Russia

Subjects

middle atmosphere, Lower thermosphere, radiation-belt electrons, energetic electron precipitation, mesosphere, lower thermosphere, geomagnetic forcing, energetic particle precipitation, ddc:538.7, Middle atmosphere, Energetic electron precipitation, Mesosphere, Earth sciences, Geophysics, Energetic particle precipitation, Space and Planetary Science, Particle precipitation, ddc:550, Geomagnetic forcing

Abstract

Precipitating auroral and radiation belt electrons are considered to play an important part in the natural forcing of the middle atmosphere with a possible impact on the climate system. Recent studies suggest that this forcing is underestimated in current chemistry‐climate models. The HEPPA III intercomparison experiment is a collective effort to address this point. In this study, we apply electron ionization rates from three data‐sets in four chemistry‐climate models during a geomagnetically active period in April 2010. Results are evaluated by comparison with observations of nitric oxide (NO) in the mesosphere and lower thermosphere. Differences between the ionization rate data‐sets have been assessed in a companion study. In the lower thermosphere, NO densities differ by up to one order of magnitude between models using the same ionization rate data‐sets due to differences in the treatment of NO formation, model climatology, and model top height. However, a good agreement in the spatial and temporal variability of NO with observations lends confidence that the electron ionization is represented well above 80 km. In the mesosphere, the averages of model results from all chemistry‐climate models differ consistently with the differences in the ionization‐rate data‐sets, but are within the spread of the observations, so no clear assessment on their comparative validity can be provided. However, observed enhanced amounts of NO in the mid‐mesosphere below 70 km suggest a relevant contribution of the high‐energy tail of the electron distribution to the hemispheric NO budget during and after the geomagnetic storm on April 6., Key Points: Differences between multi‐model mean results at high latitudes are consistent with differences in the ionization rate data‐sets used. Electron precipitation above 80 km is well reproduced for all ionization rate data‐sets despite large differences between individual CCMs. Anisotropic precipitation from ≥300 keV electrons could provide up to 0.05–0.15 Gmol NO per hemisphere in storm main and recovery phase., Norwegian Research Council (NRC), Research Council of Norway, Agencia Estatal de Investigación of the Ministerio de Ciencia, Innovación y Universidades, Instituto de Astrofísica de Andalucía, Russian Foundation for Basic Research, Ministry of Science and Higher Education of the Russian Federation, Russian Science Foundation, Academy of Finland, German Aerospace Center, German Science Foundation, Ministry of Science, Research and the Arts Baden‐Württemberg, Federal Ministry of Education and Research, International Space Science Institute

Published

2021