The imaging magnetograph eXperiment for the SUNRISE balloon Antarctica project

Martinez Pillet, Valentin; Bonet, Jose A.; Collados, Manuel V.; Jochum, Lieselotte; Mathew, S.; Medina Trujillo, J. L.; Ruiz Cobo, B.; del Toro Iniesta, Jose Carlos; Lopez Jimenez, A. C.; Castillo Lorenzo, J.; Herranz, M.; Jeronimo, J. M.; Mellado, P.; Morales, R.; Rodriguez, J.; Alvarez-Herrero, Alberto; Belenguer, Tomas; Heredero, R. L.; Menendez, M.; Ramos, G.; Reina, Manuel; Pastor, C.; Sanchez, A.; Villanueva, J.; Domingo, Vicente; Gasent, J. L.; Rodriguez, P.
Referencia bibliográfica

Optical, Infrared, and Millimeter Space Telescopes. Edited by Mather, John C. Proceedings of the SPIE, Volume 5487, pp. 1152-1164 (2004).

Fecha de publicación:
10
2004
Número de autores
27
Número de autores del IAC
7
Número de citas
23
Número de citas referidas
19
Descripción
The SUNRISE balloon project is a high-resolution mission to study solar magnetic fields able to resolve the critical scale of 100 km in the solar photosphere, or about one photon mean free path. The Imaging Magnetograph eXperiment (IMaX) is one of the three instruments that will fly in the balloon and will receive light from the 1m aperture telescope of the mission. IMaX should take advantage of the 15 days of uninterrupted solar observations and the exceptional resolution to help clarifying our understanding of the small-scale magnetic concentrations that pervade the solar surface. For this, IMaX should act as a diffraction limited imager able to carry out spectroscopic analysis with resolutions in the 50.000-100.000 range and capable to perform polarization measurements. The solutions adopted by the project to achieve all these three demanding goals are explained in this article. They include the use of Liquid Crystal Variable Retarders for the polarization modulation, one LiNbO3 etalon in double pass and two modern CCD detectors that allow for the application of phase diversity techniques by slightly changing the focus of one of the CCDs.