Your search keyword '"Schellart, P."' showing total 17 results

1. Updated Calibration of the LOFAR Low-Band Antennas

Author

Mulrey, K., Bonardi, A., Buitink, S., Corstanje, A., Falcke, H., Hare, B. M., Horandel, J., Mitra, P., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., Scholten, O., ter Veen, S., Thoudam, Satyendra, Trinh, T. N. G., Winchen, T., Mulrey, K., Bonardi, A., Buitink, S., Corstanje, A., Falcke, H., Hare, B. M., Horandel, J., Mitra, P., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., Scholten, O., ter Veen, S., Thoudam, Satyendra, Trinh, T. N. G., and Winchen, T.

Abstract

The LOw-Frequency ARray (LOFAR) telescope measures radio emission from air showers. In order to interpret the data, an absolute, frequency dependent calibration is required. Due to a growing need for a better understanding of the measured frequency spectrum, we revisit the calibration of the LOFAR antennas in the range of 30-80 MHz. Using the galactic radio emission and a detailed model of the LOFAR signal chain, we find a calibration that provides an absolute energy scale and allows us to study frequency dependent features in measured air shower signals.

Published

2019

2. Calibration of the LOFAR low-band antennas using the Galaxy and a model of the signal chain

Author

Mulrey, K., Bonardi, A., Buitink, S., Corstanje, A., Falcke, H., Hare, B. M., Horandel, J. R., Huege, T., Mitra, P., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., Scholtene, O., ter Veen, S., Thoudam, Satyendra, Trinh, T. N. G., Winchen, T., Mulrey, K., Bonardi, A., Buitink, S., Corstanje, A., Falcke, H., Hare, B. M., Horandel, J. R., Huege, T., Mitra, P., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., Scholtene, O., ter Veen, S., Thoudam, Satyendra, Trinh, T. N. G., and Winchen, T.

Abstract

The LOw-Frequency ARray (LOFAR) is used to make precise measurements of radio emission from extensive air showers, yielding information about the primary cosmic ray. Interpreting the measured data requires an absolute and frequency-dependent calibration of the LOFAR system response. This is particularly important for spectral analyses, because the shape of the detected signal holds information about the shower development. We revisit the calibration of the LOFAR antennas in the range of 30-80 MHz. Using the Galactic emission and a detailed model of the LOFAR signal chain, we find an improved calibration that provides an absolute energy scale and allows for the study of frequency dependent features in measured signals. With the new calibration, systematic uncertainties of 13% are reached, and comparisons of the spectral shape of calibrated data with simulations show promising agreement. (C) 2019 Elsevier B.V. All rights reserved.

Published

2019

3. LOFAR Lightning Imaging : Mapping Lightning With Nanosecond Precision

Author

Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., Winchen, T., Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., and Winchen, T.

Abstract

Lightning mapping technology has proven instrumental in understanding lightning. In this work we present a pipeline that can use lightning observed by the LOw-Frequency ARray (LOFAR) radio telescope to construct a 3-D map of the flash. We show that LOFAR has unparalleled precision, on the order of meters, even for lightning flashes that are over 20km outside the area enclosed by LOFAR antennas (approximate to 3,200km(2)), and can potentially locate over 10,000 sources per lightning flash. We also show that LOFAR is the first lightning mapping system that is sensitive to the spatial structure of the electrical current during individual lightning leader steps.

Published

2018

4. LOFAR Lightning Imaging : Mapping Lightning With Nanosecond Precision

Author

Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., Winchen, T., Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., and Winchen, T.

Abstract

Lightning mapping technology has proven instrumental in understanding lightning. In this work we present a pipeline that can use lightning observed by the LOw-Frequency ARray (LOFAR) radio telescope to construct a 3-D map of the flash. We show that LOFAR has unparalleled precision, on the order of meters, even for lightning flashes that are over 20km outside the area enclosed by LOFAR antennas (approximate to 3,200km(2)), and can potentially locate over 10,000 sources per lightning flash. We also show that LOFAR is the first lightning mapping system that is sensitive to the spatial structure of the electrical current during individual lightning leader steps.

Published

2018

5. LOFAR Lightning Imaging : Mapping Lightning With Nanosecond Precision

Author

Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., Winchen, T., Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., and Winchen, T.

Abstract

Lightning mapping technology has proven instrumental in understanding lightning. In this work we present a pipeline that can use lightning observed by the LOw-Frequency ARray (LOFAR) radio telescope to construct a 3-D map of the flash. We show that LOFAR has unparalleled precision, on the order of meters, even for lightning flashes that are over 20km outside the area enclosed by LOFAR antennas (approximate to 3,200km(2)), and can potentially locate over 10,000 sources per lightning flash. We also show that LOFAR is the first lightning mapping system that is sensitive to the spatial structure of the electrical current during individual lightning leader steps.

Published

2018

6. LOFAR Lightning Imaging : Mapping Lightning With Nanosecond Precision

Author

Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., Winchen, T., Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., and Winchen, T.

Abstract

Lightning mapping technology has proven instrumental in understanding lightning. In this work we present a pipeline that can use lightning observed by the LOw-Frequency ARray (LOFAR) radio telescope to construct a 3-D map of the flash. We show that LOFAR has unparalleled precision, on the order of meters, even for lightning flashes that are over 20km outside the area enclosed by LOFAR antennas (approximate to 3,200km(2)), and can potentially locate over 10,000 sources per lightning flash. We also show that LOFAR is the first lightning mapping system that is sensitive to the spatial structure of the electrical current during individual lightning leader steps.

Published

2018

7. LOFAR Lightning Imaging : Mapping Lightning With Nanosecond Precision

Author

Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., Winchen, T., Hare, B. M., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Falcke, H., Horandel, J. R., Leijnse, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, Trinh, T. N. G., ter Veen, S., and Winchen, T.

Abstract

Lightning mapping technology has proven instrumental in understanding lightning. In this work we present a pipeline that can use lightning observed by the LOw-Frequency ARray (LOFAR) radio telescope to construct a 3-D map of the flash. We show that LOFAR has unparalleled precision, on the order of meters, even for lightning flashes that are over 20km outside the area enclosed by LOFAR antennas (approximate to 3,200km(2)), and can potentially locate over 10,000 sources per lightning flash. We also show that LOFAR is the first lightning mapping system that is sensitive to the spatial structure of the electrical current during individual lightning leader steps.

Published

2018

8. Thunderstorm electric fields probed by extensive air showers through their polarized radio emission

Author

Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., Winchen, T., Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., and Winchen, T.

Abstract

We observe a large fraction of circular polarization in radio emission from extensive air showers recorded during thunderstorms, much higher than in the emission from air showers measured during fair-weather circumstances. We show that the circular polarization of the air showers measured during thunderstorms can be explained by the change in the direction of the transverse current as a function of altitude induced by atmospheric electric fields. Thus by using the full set of Stokes parameters for these events, we obtain a good characterization of the electric fields in thunderclouds. We also measure a large horizontal component of the electric fields in the two events that we have analyzed.

Published

2017

9. Thunderstorm electric fields probed by extensive air showers through their polarized radio emission

Author

Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., Winchen, T., Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., and Winchen, T.

Abstract

We observe a large fraction of circular polarization in radio emission from extensive air showers recorded during thunderstorms, much higher than in the emission from air showers measured during fair-weather circumstances. We show that the circular polarization of the air showers measured during thunderstorms can be explained by the change in the direction of the transverse current as a function of altitude induced by atmospheric electric fields. Thus by using the full set of Stokes parameters for these events, we obtain a good characterization of the electric fields in thunderclouds. We also measure a large horizontal component of the electric fields in the two events that we have analyzed.

Published

2017

10. Thunderstorm electric fields probed by extensive air showers through their polarized radio emission

Author

Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., Winchen, T., Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., and Winchen, T.

Abstract

We observe a large fraction of circular polarization in radio emission from extensive air showers recorded during thunderstorms, much higher than in the emission from air showers measured during fair-weather circumstances. We show that the circular polarization of the air showers measured during thunderstorms can be explained by the change in the direction of the transverse current as a function of altitude induced by atmospheric electric fields. Thus by using the full set of Stokes parameters for these events, we obtain a good characterization of the electric fields in thunderclouds. We also measure a large horizontal component of the electric fields in the two events that we have analyzed.

Published

2017

11. Thunderstorm electric fields probed by extensive air showers through their polarized radio emission

Author

Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., Winchen, T., Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., and Winchen, T.

Abstract

We observe a large fraction of circular polarization in radio emission from extensive air showers recorded during thunderstorms, much higher than in the emission from air showers measured during fair-weather circumstances. We show that the circular polarization of the air showers measured during thunderstorms can be explained by the change in the direction of the transverse current as a function of altitude induced by atmospheric electric fields. Thus by using the full set of Stokes parameters for these events, we obtain a good characterization of the electric fields in thunderclouds. We also measure a large horizontal component of the electric fields in the two events that we have analyzed.

Published

2017

12. Circular polarization of radio emission from air showers in thunderstorm conditions

Author

Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Mitra, P., Mulrey, K., Nelles, A., Thoudam, Satyendra, Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., ter Veen, S., Winchen, T., Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Mitra, P., Mulrey, K., Nelles, A., Thoudam, Satyendra, Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., ter Veen, S., and Winchen, T.

Abstract

We present measured radio emission from cosmic-ray-induced air showers under thunderstorm conditions. We observe for these events large differences in intensity, linear polarization and circular polarization from the events measured under fair-weather conditions. This can be explained by the effects of atmospheric electric fields in thunderclouds. Therefore, measuring the intensity and polarization of radio emission from cosmic ray extensive air showers during thunderstorm conditions provides a new tool to probe the atmospheric electric fields present in thunderclouds.

Published

2017

13. The mass composition of cosmic rays measured with LOFAR

Author

Horandel, Jorg R., Bonardi, A., Buitink, S., Corstanje, A., Falcke, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., Scholten, O., ter Veen, S., Thoudam, Satyendra, Trinh, T. N. G., Winchen, T., Horandel, Jorg R., Bonardi, A., Buitink, S., Corstanje, A., Falcke, H., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., Scholten, O., ter Veen, S., Thoudam, Satyendra, Trinh, T. N. G., and Winchen, T.

Abstract

High-energy cosmic rays, impinging on the atmosphere of the Earth initiate cascades of secondary particles, the extensive air showers. The electrons and positrons in the air shower emit electromagnetic radiation. This emission is detected with the LOFAR radio telescope in the frequency range from 30 to 240 MHz. The data are used to determine the properties of the incoming cosmic rays. The radio technique is now routinely used to measure the arrival direction, the energy, and the particle type (atomic mass) of cosmic rays in the energy range from 10(17) to 10(18) eV. This energy region is of particular astrophysical interest, since in this regime a transition from a Galactic to an extra-galactic origin of cosmic rays is expected. For illustration, the LOFAR results are used to set constraints on models to describe the origin of high-energy cosmic rays.

Published

2017

14. Thunderstorm electric fields probed by extensive air showers through their polarized radio emission

Author

Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., Winchen, T., Trinh, T. N. G., Scholten, O., Bonardi, A., Buitink, S., Corstanje, A., Ebert, U., Enriquez, J. E., Falcke, H., Horandel, J. R., Hare, B. M., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Rutjes, C., Schellart, P., Thoudam, Satyendra, ter Veen, S., and Winchen, T.

Abstract

We observe a large fraction of circular polarization in radio emission from extensive air showers recorded during thunderstorms, much higher than in the emission from air showers measured during fair-weather circumstances. We show that the circular polarization of the air showers measured during thunderstorms can be explained by the change in the direction of the transverse current as a function of altitude induced by atmospheric electric fields. Thus by using the full set of Stokes parameters for these events, we obtain a good characterization of the electric fields in thunderclouds. We also measure a large horizontal component of the electric fields in the two events that we have analyzed.

Published

2017

15. Circular polarization in radio emission from extensive air showers

Author

Scholten, O., Trinh, T. N. G., Bonardi, A., Buitink, S., Corstanje, A., Falcke, H., Hare, B. M., Hörandel, J. R., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., ter Veen, S., Thoudam, Satyendra, Winchen, T., Scholten, O., Trinh, T. N. G., Bonardi, A., Buitink, S., Corstanje, A., Falcke, H., Hare, B. M., Hörandel, J. R., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., ter Veen, S., Thoudam, Satyendra, and Winchen, T.

Abstract

At LOFAR we measure the radio emission from extensive air showers (EAS) in the frequency band of 30 - 80 MHz in dual-polarized antennas. Through an accurate antenna calibration we can determine the complete set of four Stokes parameters that uniquely determine the linear and circular polarization of the radio signal for an EAS. The observed dependency of the circular polarization on azimuth angle and distance to the shower axis is explained as due to the interfering contributions from the two different radiation mechanisms, a main contribution due to a geomagnetically-induced transverse current and a secondary component due to the Askaryan effect. The measured data show a quantitative agreement with microscopic CORSIKA/CoREAS calculations. Having a very detailed understanding of radio emission from EAS, opens the possibility to use circular polarization as an investigative tool in the analysis of air shower structure, such as for the determination of atmospheric electric fields., Free fulltext at: https://pos.sissa.it/301/324

Published

2017

16. Measurement of cosmic rays with LOFAR

Author

Rossetto, L., Buitink, S., Corstanje, A., Enriquez, J. E., Falcke, H., Horandel, J. R., Nelles, A., Rachen, J. P., Schellart, P., Scholten, O., ter Veen, S., Thoudam, Satyendra, Trinh, T. N. G., Rossetto, L., Buitink, S., Corstanje, A., Enriquez, J. E., Falcke, H., Horandel, J. R., Nelles, A., Rachen, J. P., Schellart, P., Scholten, O., ter Veen, S., Thoudam, Satyendra, and Trinh, T. N. G.

Abstract

The LOw Frequency ARay (LOFAR) is a multipurpose radio -antenna array aimed to detect radio signals in the 10 - 240 MHz frequency range, covering a large surface in Northern Europe with a higher density in the Northern Netherlands. Radio emission in the atmosphere is produced by cosmic -ray induced air showers through the interaction of charged particles with the Earth magnetic field. The detection of radio signals allows to reconstruct several properties of the observed cascade. We review here all important results achieved in the last years. We proved that the radio -signal distribution at ground level is described by a two-dimensional pattern, which is well fitted by a double Gaussian function. The radio -signal arrival time and polarization have been measured, thus providing additional information on the extensive air shower geometry, and on the radio emission processes. We also showed that the radio signal reaches ground in a thin, curved wavefront which is best parametrized by a hyperboloid shape centred around the shower axis. Radio emission has also been studied under thunderstorm conditions and compared to fair weather conditions. Moreover, by using a hybrid reconstruction technique, we performed mass composition measurements in the energy range 10(17) - 10(18) eV.

Published

2016

17. Measurement of the circular polarization in radio emission from extensive air showers confirms emission mechanisms

Author

Scholten, O., Trinh, T. N. G., Bonardi, A., Buitink, S., Correa, P., Corstanje, A., Hasankiadeh, Q. Dorosti, Falcke, H., Horandel, J. R., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., Thoudam, Satyendra, ter Veen, S., de Vries, K. D., Winchen, T., Scholten, O., Trinh, T. N. G., Bonardi, A., Buitink, S., Correa, P., Corstanje, A., Hasankiadeh, Q. Dorosti, Falcke, H., Horandel, J. R., Mitra, P., Mulrey, K., Nelles, A., Rachen, J. P., Rossetto, L., Schellart, P., Thoudam, Satyendra, ter Veen, S., de Vries, K. D., and Winchen, T.

Abstract

We report here on a novel analysis of the complete set of four Stokes parameters that uniquely determine the linear and/or circular polarization of the radio signal for an extensive air shower. The observed dependency of the circular polarization on azimuth angle and distance to the shower axis is a clear signature of the interfering contributions from two different radiation mechanisms, a main contribution due to a geomagnetically-induced transverse current and a secondary component due to the build-up of excess charge at the shower front. The data, as measured at LOFAR, agree very well with a calculation from first principles. This opens the possibility to use circular polarization as an investigative tool in the analysis of air shower structure, such as for the determination of atmospheric electric fields.

Published

2016