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Post Info TOPIC: LOPES
Blobrana


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Title: LOPES 3D reconfiguration and first measurements
Authors: D. Huber, W.D. Apel, J.C. Arteaga, L. Bähren, K. Bekk, M. Bertaina, P.L. Biermann, J. Blümer, H. Bozdog, I.M. Brancus, P. Buchholz, E. Cantoni, A. Chiavassa, K. Daumiller, V. de Souza, F. Di Pierro, P. Doll, R. Engel, H. Falcke, M. Finger, B. Fuchs, D. Fuhrmann, H. Gemmeke, C. Grupen, A. Haungs, D. Heck, J.R. Hörandel, A. Horneffer, T. Huege, P.G. Isar, K.-H. Kampert, D. Kang, O. Krömer, J. Kuijpers, K. Link, P. Luczak, M. Ludwig, H.J. Mathes, M. Melissas, C. Morello, J. Oehlschläger, N. Palmieri, T. Pierog, J. Rautenberg, H. Rebel, M. Roth, C. Rühle, A. Saftoiu, H. Schieler, A. Schmidt, F.G. Schröder, O. Sima, G. Toma, G.C. Trinchero, A. Weindl, J. Wochele, M. Wommer, J. Zabierowski, J.A. Zensus

The Radio detection technique of high-energy cosmic rays is based on the radio signal emitted by the charged particles in an air shower due to their deflection in the Earth's magnetic field. The LOPES experiment at Karlsruhe Institute of Technology, Germany with its simple dipoles made major contributions to the revival of this technique. LOPES is working in the frequency range from 40 to 80 MHz and was reconfigured several times to improve and further develop the radio detection technique. In the current setup LOPES consists of 10 tripole antennas which measure the complete electric field vector of the radio emission from cosmic rays. LOPES is the first experiment measuring all three vectorial components at once and thereby gaining the full information about the electric field vector and not only a two-dimensional projection. Such a setup including also measurements of the vertical electric field component is expected to increase the sensitivity to inclined showers and help to advance the understanding of the emission mechanism. We present the reconfiguration and calibration procedure of LOPES 3D and discuss first measurements.

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Blobrana


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LOPES 3D
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Title: LOPES 3D - vectorial measurements of radio emission from cosmic ray induced air showers
Authors: W.D. Apel, J.C. Arteaga, L. Bähren, K. Bekk, M. Bertaina, P.L. Biermann, J. Blümer, H. Bozdog, I.M. Brancus, A. Chiavassa, K. Daumiller, V. de Souza, F. Di Pierro, P. Doll, R. Engel, H. Falcke, B. Fuchs, D. Fuhrmann, H. Gemmeke, C. Grupen, A. Haungs, D. Heck, J.R. Hörandel, A. Horneffer, D. Huber, T. Huege, P.G. Isar, K.-H. Kampert, D. Kang, O. Krömer, J. Kuijpers, K. Link, P. Luczak, M. Ludwig, H.J. Mathes, M. Melissas, C. Morello, J. Oehlschläger, N. Palmieri, T. Pierog, J. Rautenberg, H. Rebel, M. Roth, C. Rühle, A. Saftoiu, H. Schieler, A. Schmidt, F.G. Schröder, O. Sima, G. Toma, G.C. Trinchero, A. Weindl, J. Wochele, J. Zabierowski, J.A. Zensus

LOPES 3D is able to measure all three components of the electric field vector of the radio emission from air showers. This allows a better comparison with emission models. The measurement of the vertical component increases the sensitivity to inclined showers. By measuring all three components of the electric field vector LOPES 3D demonstrates by how much the reconstruction accuracy of primary cosmic ray parameters increases. Thus LOPES 3D evaluates the usefulness of vectorial measurements for large scale applications.

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LOPES-3D
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Title: LOPES-3D, an antenna array for full signal detection of air-shower radio emission
Authors: W.D. Apel, J.C. Arteaga, L. Bähren, K. Bekk, M. Bertaina, P.L. Biermann, J. Blümer, H. Bozdog, I.M. Brancus, P. Buchholz, E. Cantoni, A. Chiavassa, K. Daumiller, V. de Souza, F. Di Pierro, P. Doll, R. Engel, H. Falcke, M. Finger, B. Fuchs, D. Fuhrmann, H. Gemmeke, C. Grupen, A. Haungs, D. Heck, J.R. Hörandel, A. Horneffer, D. Huber, T. Huege, P.G. Isar, K.-H. Kampert, D. Kang, O. Krömer, J. Kuijpers, K. Link, P. Luczak, M. Ludwig, H. J. Mathes, M. Melissas, C. Morello, J. Oehlschläger, N. Palmieri, T. Pierog, J. Rautenberg, H. Rebel, M. Roth, C. Rühle, A. Saftoiu, H. Schieler, A. Schmidt, F. G. Schröder, O. Sima, G. Toma, G.C. Trinchero, A. Weindl, J. Wochele, M. Wommer, J. Zabierowski, J.A. Zensus

To better understand the radio signal emitted by extensive air-showers and to further develop the radio detection technique of high-energy cosmic rays, the LOPES experiment was reconfigured to LOPES-3D. LOPES-3D is able to measure all three vectorial components of the electric field of radio emission from cosmic ray air showers. The additional measurement of the vertical component ought to increase the reconstruction accuracy of primary cosmic ray parameters like direction and energy, provides an improved sensitivity to inclined showers, and will help to validate simulation of the emission mechanisms in the atmosphere. LOPES-3D will evaluate the feasibility of vectorial measurements for large scale applications. In order to measure all three electric field components directly, a tailor-made antenna type (tripoles) was deployed. The change of the antenna type necessitated new pre-amplifiers and an overall recalibration. The reconfiguration and the recalibration procedure are presented and the operationality of LOPES-3D is demonstrated.

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Ultra-high energy cosmic ray flash



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Cosmic-ray radio_flash.mpg [file size 322K]

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A small prototype array in Germany has detected several radio flashes from cosmic rays that smack into the Earth’s upper atmosphere.
A larger array, with more of these low-cost radio antennas, could help astrophysicists decipher the mystery behind the highest energy cosmic rays.
Cosmic rays are particles (mostly atomic nuclei) with energies above 10^10 eV (sometimes even beyond 10^20 eV) that are accelerated in highly energetic cosmic phenomena like supernovae, black hole jets, …
The exact processes in which they are produced are unknown, but they can be detected through their collisions with particles in the atmosphere.
From these collisions come showers of secondary particles – including electrons, anti-electrons (positrons), and muons, which are like heavy electrons. Cosmic rays can be characterized by the showers they produce.



Surprisingly, some of these space-faring projectiles have a 100 million times more energy than is possible in man-made accelerators. There are no "cosmic accelerators" in our galactic neighbourhood that seem powerful enough to generate particles with this much energy.
Therefore, these so-called ultra-high energy cosmic rays (UHECRs) presumably come from colliding galaxies or large black holes hundreds of millions of light years away.
But that raises a problem: cosmic dust and gas along the way will slow – or even outright destroy – high-energy particles travelling these great distances.
Added to this quandary is the fact that no one knows the true identity of UHECRs. The usual suspects are protons, heavy nuclei like iron, gamma rays, and weakly-interacting neutrinos.
Sorting out the origin and nature of UHECRs is part of the impetus of the LOPES (LOFAR Prototype Station) experiment. This array of 10 low-cost radio antennas captures flashes emitted by a shower’s electrons and positrons, as they interact with the Earth’s magnetic field.
The more energy in the initial cosmic ray, the more radio emission.
"It is amazing that with simple FM radio antennas we can measure the energy of particles coming from the cosmos. If we had sensitive radio eyes, we would see the sky sparkle with radio flashes." - Heino Falcke, spokesperson for the LOPES collaboration.



The radio bursts only last a few billionths of a second. But during that short time, they are the brightest spots in the radio sky. LOPES picks up the flashes between 43 and 73 MHz – just below the FM dial.
LOPES has not yet detected any flashes from UHECRs. To do so would probably require a larger set of detectors, since a square mile of the Earth’s atmosphere is hit by an UHECR only once a century. Bigger radio arrays, such as the Low-Frequency Array (LOFAR) and Square Kilometre Array (SKA), are currently in development.
But LOPES has helped in calibrating the radio flashes. This is because it is situated inside the KASCADE (Karlsuhe Shower Core and Array Detector) experiment, which measures the number of muons that rain down from cosmic ray showers.

"This is indeed an unusual combination, where nuclear physicists and radio astronomers work together to create a unique and highly original astroparticle physics experiment." - Anton Zensus from the Max-Planck Institut fuer Radioastronomie (MPIfR) in Bonn.

By comparing the radio flash to the muon count, scientists hope to eventually tell which of the suspected particles make up UHECRs. For a given radio signal, a proton – for example – would produce many more muons than would a gamma ray.

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