Terrestrial Planet Optical Phase Curves. I. Direct Measurements of the Earth

• Published in: The Astronomical journal Vol. 163; no. 1; pp. 5 - 13
• Main Authors: De Cock, Roderick, Livengood, Timothy A., Stam, Daphne M., Lisse, Carey M., Hewagama, Tilak, Deming, L. Drake
• Format: Journal Article
• Language: English
• Published: Goddard Space Flight Center The American Astronomical Society 01.01.2022; American Astronomical Society; IOP Publishing
• Subjects: Albedo; Astronomy; Deep Impact Mission (NASA); Earth; Earth (planet); Exobiology; Exoplanets; Extrasolar planets; Observational astronomy; Optical astronomy; Phase angle; Space missions; Spacecraft; Terrestrial planets
• ISSN: 0004-6256; 1538-3881
• DOI: 10.3847/1538-3881/ac3234

NASA’s EPOXI mission used the Deep Impact spacecraft to observe the disk-integrated Earth as an analog to terrestrial exoplanets’ appearance. The mission took five 24 hr observations in 2008–2009 at various phase angles(57°.7–86°.4)and ranges(0.11–0.34 au), of which three equatorial(E1, E4, E5)and two polar(P1, North and P2,South). The visible data taken by the HRIV instrument ranges from 0.3 to 1.0μm, taken trough seven spectral filters that have spectral widths of about 100 nm, and which are centered about 100 nm apart, from 350 to 950 nm. The disk-integrated, 24 hr averaged signal is used in a phase angle analysis. A Lambertian-reflecting, spherical planet model is used to estimate geometric albedo for every observation and wavelength. The geometric albedos range from 0.143(E1, 950 nm)to 0.353(P2, 350 nm)and show wavelength dependence. The equatorial observations have similar values, while the polar observations have higher values due to the ice in view. Therefore, equatorial observations can be predicted for other phase angles, but(Earth-like)polar views(with ice)would be underestimated.