Your search keyword '"Amadeo Bellotti"' showing total 2 results

1. MWR: Microwave Radiometer for the Juno Mission to Jupiter

Author

J. G. Kempenaar, R. Williamson, M. S. Zawadski, J. K. Arballo, Neil Chamberlain, Behrouz Khayatian, T. C. Owen, B. R. Franklin, Paul G. Steffes, R. C. Hughes, M. A. Janssen, Sushil K. Atreya, Amadeo Bellotti, Jonathan I. Lunine, Richard Hodges, C. C. Wang, Scott Bolton, Sidharth Misra, Steven Levin, Andrew P. Ingersoll, Samuel Gulkis, Liming Li, K. A. Lee, Glenn S. Orton, E. Sarkissian, A. Ulloa-Severino, V. Vorperion, A. S. Sahakian, J. C. Chen, L. A. Jewell, P. J. Pingree, Henry A. Conley, Daniel Santos-Costa, D. Gautier, Michael Allison, Shannon Brown, Fabiano Oyafuso, M. S. Loo, Cheng Li, Douglas Dawson, F. Maiwald, J. E. Oswald, Damon Russell, William Hatch, E. T. Sunada, Virgil Adumitroaie, Richard Redick, A. S. Mazer, G. Bedrosian, and Amarit Kitiyakara

Subjects

Physics, 010504 meteorology & atmospheric sciences, Microwave radiometer, Atmosphere of Jupiter, Astronomy and Astrophysics, 01 natural sciences, Jovian, Jupiter, Atmosphere, Exploration of Jupiter, Space and Planetary Science, Brightness temperature, Physics::Space Physics, 0103 physical sciences, Astrophysics::Earth and Planetary Astrophysics, Orbit insertion, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences, Remote sensing

Abstract

The Juno Microwave Radiometer (MWR) is a six-frequency scientific instrument designed and built to investigate the deep atmosphere of Jupiter. It is one of a suite of instruments on NASA’s New Frontiers Mission Juno launched to Jupiter on August 5, 2011. The focus of this paper is the description of the scientific objectives of the MWR investigation along with the experimental design, observational approach, and calibration that will achieve these objectives, based on the Juno mission plan up to Jupiter orbit insertion on July 4, 2016. With frequencies distributed approximately by octave from 600 MHz to 22 GHz, the MWR will sample the atmospheric thermal radiation from depths extending from the ammonia cloud region at around 1 bar to pressure levels as deep as 1000 bars. The primary scientific objectives of the MWR investigation are to determine the presently unknown dynamical properties of Jupiter’s subcloud atmosphere and to determine the global abundance of oxygen and nitrogen, present in the atmosphere as water and ammonia deep below their respective cloud decks. The MWR experiment is designed to measure both the thermal radiation from Jupiter and its emission-angle dependence at each frequency relative to the atmospheric local normal with high accuracy. The antennas at the four highest frequencies (21.9, 10.0, 5.2, and 2.6 GHz) have ∼12° beamwidths and will achieve a spatial resolution approaching 600 km near perijove. The antennas at the lowest frequencies (0.6 and 1.25 GHz) are constrained by physical size limitations and have 20° beamwidths, enabling a spatial resolution of as high as 1000 km to be obtained. The MWR will obtain Jupiter’s brightness temperature and its emission-angle dependence at each point along the subspacecraft track, over angles up to 60° from the normal over most latitudes, during at least six perijove passes after orbit insertion. The emission-angle dependence will be obtained for all frequencies to an accuracy of better than one part in 10^3, sufficient to detect small variations in atmospheric temperature and absorber concentration profiles that distinguish dynamical and compositional properties of the deep Jovian atmosphere.

Published

2017

2. High-Precision Laboratory Measurements Supporting Retrieval of Water Vapor, Gaseous Ammonia, and Aqueous Ammonia Clouds with the Juno Microwave Radiometer (MWR)

Author

Sahand Noorizadeh, Michael Janssen, Kiruthika Devaraj, Amadeo Bellotti, Thomas R. Hanley, Danny Duong, Bryan M. Karpowicz, Paul G. Steffes, Garrett Chinsomboon, and Scott Bolton

Subjects

010504 meteorology & atmospheric sciences, Microwave radiometer, Atmosphere of Jupiter, Astronomy and Astrophysics, Atmospheric sciences, 01 natural sciences, Jovian, Jupiter, Space and Planetary Science, 0103 physical sciences, Radiative transfer, Environmental science, Absorption (electromagnetic radiation), 010303 astronomy & astrophysics, Water vapor, Microwave, 0105 earth and related environmental sciences, Remote sensing

Abstract

The NASA Juno mission includes a six-channel microwave radiometer system (MWR) operating in the 1.3–50 cm wavelength range in order to retrieve abundances of ammonia and water vapor from the microwave signature of Jupiter (see Janssen et al. 2016). In order to plan observations and accurately interpret data from such observations, over 6000 laboratory measurements of the microwave absorption properties of gaseous ammonia, water vapor, and aqueous ammonia solution have been conducted under simulated Jovian conditions using new laboratory systems capable of high-precision measurement under the extreme conditions of the deep atmosphere of Jupiter (up to 100 bars pressure and 505 K temperature). This is one of the most extensive laboratory measurement campaigns ever conducted in support of a microwave remote sensing instrument. New, more precise models for the microwave absorption from these constituents have and are being developed from these measurements. Application of these absorption properties to radiative transfer models for the six wavelengths involved will provide a valuable planning tool for observations, and will also make possible accurate retrievals of the abundance of these constituents during and after observations are conducted.

Published

2016