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Solar System Expansion and Strong Equivalence Principle as Seen by the NASA MESSENGER Mission (2018)

Zuber, Maria T. ; Neumann, Gregory A. ; Mazarico, Erwan ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: The NASA MESSENGER mission explored the innermost planet of the solar system and obtained a rich dataset of range measurements for the determination of Mercury's ephemeris. Here we use these precise data collected over seven years to estimate parameters related to General Relativity and the evolution of the Sun. These results confirm the validity of the Strong Equivalence Principle with a significantly refined uncertainty of the Nordtvedt parameter eta=(-6.6 plus or minus 7.2)x10(exp -5) By assuming a metric theory of gravitation, we retrieved the Post-Newtonian parameter beta = 1 + (-1.6 plus or minus 1.8)x10(exp -5) and the Sun's gravitational oblateness, J(sub 2 solar)=(2.246 plus or minus 0.022)x10(exp -7). Finally, we obtain an estimate of the time variation of the Sun gravitational parameter, G (raised dot)solar mass/G solar mass =(-6.13 plus or minus 1.47)x10(exp -14), which is consistent with the expected solar mass loss due to the solar wind and interior processes. This measurement allows us to constrain |G(raised dot)|/G to be less than 4 x 10(exp -14) yr(exp -1).

Keywords: Solar Physics; Lunar and Planetary Science and Exploration

Type: GSFC-E-DAA-TN50758 , GSFC-E-DAA-TN51570 , Nature Communications (e-ISSN 2041-1723); 9; 289

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ICESAT GLAS Altimetry Measurements: Received Signal Dynamic Range and Saturation Correction (2017)

Abshire, James B. ; Dimarzio, John P. ; Brunt, Kelly M. ; [et al.]

In: Other Sources

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Publication Date: 2019-07-13

Description: NASAs Ice, Cloud, and land Elevation Satellite (ICESat), which operated between 2003 and 2009, made the first satellite-based global lidar measurement of earths ice sheet elevations, sea-ice thickness, and vegetation canopy structure. The primary instrument on ICESat was the Geoscience Laser Altimeter System (GLAS), which measured the distance from the spacecraft to the earth's surface via the roundtrip travel time of individual laser pulses. GLAS utilized pulsed lasers and a direct detection receiver consisting of a silicon avalanche photodiode and a waveform digitizer. Early in the mission, the peak power of the received signal from snow and ice surfaces was found to span a wider dynamic range than anticipated, often exceeding the linear dynamic range of the GLAS 1064-nm detector assembly. The resulting saturation of the receiver distorted the recorded signal and resulted in range biases as large as approximately 50 cm for ice- and snow-covered surfaces. We developed a correction for this saturation range bias based on laboratory tests using a spare flight detector, and refined the correction by comparing GLAS elevation estimates with those derived from Global Positioning System surveys over the calibration site at the salar de Uyuni, Bolivia. Applying the saturation correction largely eliminated the range bias due to receiver saturation for affected ICESat measurements over Uyuni and significantly reduced the discrepancies at orbit crossovers located on flat regions of the Antarctic ice sheet.

Keywords: Earth Resources and Remote Sensing; Spacecraft Instrumentation and Astrionics; Statistics and Probability

Type: GSFC-E-DAA-TN45253 , IEEE Transaction on Geoscience and Remote Sensing (ISSN 0196-2892) (e-ISSN 1558-0644); PP; 99; 1-15

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Trilogy, A Planetary Geodesy Mission Concept for Measuring the Expansion of the Solar System (2018)

Genova, Antonio ; Sun, Xiaoli ; Zuber, Maria T. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: The scale of the solar system is slowly changing, likely increasing as a result of solar mass loss, with additional change possible if there is a secular variation of the gravitational constant, G. The measurement of the change of scale could provide insight into the past and the future of the solar system, and in addition a better understanding of planetary motion and fundamental physics. Estimates for the expansion of the scale of the solar system are of order 1.5 cm year(exp -1) AU(exp -1), which over several years is an observable quantity with present-day laser ranging systems. This estimate suggests that laser measurements between planets could provide an accurate estimate of the solar system expansion rate. We examine distance measurements between three bodies in the inner solar system -- Earth's Moon, Mars and Venus -- and outline a mission concept for making the measurements. The concept involves placing spacecraft that carry laser ranging transponders in orbit around each body and measuring the distances between the three spacecraft over a period of several years. The analysis of these range measurements would allow the co-estimation of the spacecraft orbit, planetary ephemerides, other geophysical parameters related to the constitution and dynamics of the central bodies, and key geodetic parameters related to the solar system expansion, the Sun, and theoretical physics.

Keywords: Solar Physics; Lunar and Planetary Science and Exploration

Type: GSFC-E-DAA-TN52817 , Planetary and Space Science (ISSN 0032-0633); 153; 127-133

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