Dr. Ignazio F. Pillitteri Profile

Dr. Ignazio F. Pillitteri

at Istituto nazionale di astrofisica

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Publications (2)

Proceedings Article | 22 August 2024 Presentation

MANTIS 16U CubeSat mission: characterizing the high energy stellar radiation environment of exoplanetary systems with simultaneous extreme-UV through visible observations

Briana Indahl, Brian Fleming, Kevin France, David Wilson, Juan Alcala, Stefano Basso, Francesco Borsa, Amal Chandran, Marta Civitani, Vincenzo Cortroneo, Néstor Espinoza, Davide Fedele, Giancarlo Ghirlanda, Fabien Grisé, Eliza Kempton, Tommi Koskinen, Nicholas Kruczek, Jake McCoy, Randall McEntaffer, Yamila Miguel, Nicholas Nell, Brunella Nisini, Giovanni Pareschi, Ignazio Pillitteri, Peter Schneider, Davide Sisana, Stefan Ulrich, Dmitry Vorobiev, Allison Youngblood

Proceedings Volume 13093, 130930B (2024) https://doi.org/10.1117/12.3020386

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Proceedings Article | 9 September 2019 Presentation + Paper

SEEJ: SmallSat Exosphere Explorer of hot Jupiters

Scott Wolk, JaeSub Hong, Suzanne Romaine, Katja Poppenhaeger, Almus Kenter, Althea Moorhead, Dennis Gallagher, Christopher Moore, Martin Elvis, Ralph Kraft, Jeremy Drake, Vinay Kashyap, Elaine Winston, Bradford Wargelin, Ignazio Pillitteri, Diab Jerius, Mark Stahl, Bruce Wiegmann, Christopher Loghry

Proceedings Volume 11118, 111180E (2019) https://doi.org/10.1117/12.2529380

KEYWORDS: Jupiter, Stars, Planets, X-rays, X-ray detectors, Exoplanets, Atmospheric sciences, Magnetism, Atmospheric optics, Atmospheric sensing

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The first detected exoplanets found were "hot Jupiters"; these are large Jupiter-like planets in close orbits with their host star. The stars in these so-called "hot Jupiter systems" can have significant X-ray emission and the X-ray flux likely changes the evolution of the overall star-planetary system in at least two ways: (1) the intense high energy flux alters the structure of the upper atmosphere of the planet - in some cases leading to significant mass loss; (2) the angular momentum and magnetic field of the planet induces even more activity on the star, enhancing its X-rays, which are then subsequently absorbed by the planet. If the alignment of the systems is appropriate, the planet will transit the host star. The resulting drop in flux from the star allows us to measure the distribution of the low-density planetary atmosphere. We describe a science mission concept for a SmallSat Exosphere Explorer of hot Jupiters (SEEJ; pronounced "siege"). SEEJ will monitor the X-ray emission of nearby X-ray bright stars with transiting hot Jupiters in order to measure the lowest density portion of exoplanet atmospheres and the coronae of the exoplanet hosts. SEEJ will use revolutionary Miniature X-ray Optics (MiXO) and CMOS X-ray detectors to obtain sufficient collecting area and high sensitivity in a low mass, small volume and low-cost package. SEEJ will observe scores of transits occurring on select systems to make detailed measurements of the transit depth and shape which can be compared to out-of-transit behavior of the target system. The depth and duration of the flux change will allow us to characterize the exospheres of multiple hot Jupiters in a single year. In addition, the long baselines (covering multiple stellar rotation periods) from the transit data will allow us to characterize the temperature, flux and flare rates of the exoplanet hosts at an unprecedented level. This, in turn, will provide valuable constraints for models of atmospheric loss. In this contribution we outline the science of SEEJ and focus on the enabling technologies Miniature X-ray Optics and CMOS X-ray detectors.

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