Impact flux on Jupiter: From superbolides to large-scale collisions
Abbreviated Journal Title
meteorites, meteors, meteoroids; planets and satellites: atmospheres; planets and satellites: individual: Jupiter; SHOEMAKER-LEVY-9 IMPACTS; TEMPORAL EVOLUTION; CRATERING RATE; FRIEND; CLOUD; COMET; RATES; DEBRIS; IMAGES; EARTH; Astronomy & Astrophysics
Context. Regular observations of Jupiter by a large number of amateur astronomers have resulted in the serendipitous discovery of short bright flashes in its atmosphere, which have been proposed as being caused by impacts of small objects. Three flashes were detected: one on June 3, 2010, one on August 20, 2010, and one on September 10, 2012. Aims. We show that the flashes are caused by impacting objects that we characterize in terms of their size, and we study the flux of small impacts on Jupiter. Methods. We measured the light curves of these atmospheric airbursts to extract their luminous energy and computed the masses and sizes of the objects. We ran simulations of impacts and compared them with the light curves. We analyzed the statistical significance of these events in the large pool of Jupiter observations. Results. All three objects are in the 5-20 m size category depending on their density, and they released energy comparable to the recent Chelyabinsk airburst. Model simulations approximately agree with the interpretation of the limited observations. Biases in observations of Jupiter suggest a rate of 12-60 similar impacts per year and we provide software tools for amateurs to examine the faint signature of impacts in their data to increase the number of detected collisions. Conclusions. The impact rate agrees with dynamical models of comets. More massive objects (a few 100 m) should impact with Jupiter every few years leaving atmospheric dark debris features that could be detectable about once per decade.
Astronomy & Astrophysics
"Impact flux on Jupiter: From superbolides to large-scale collisions" (2013). Faculty Bibliography 2010s. 4130.