Meteorological results from the surface of Mars: Viking 1 and 2

Hess, Siegfried; Henry, Robert; Leovy, Conway Β.; Ryan, Jack; Tillman, J. E.

doi:10.1029/js082i028p04559

Cited by 294 publications

(208 citation statements)

References 25 publications

(11 reference statements)

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“…After several failures, the first successful meteorological observations from the Martian surface were made in 1976 by the two Viking landers (Chamberlain et al 1976;Hess et al 1977;Tillman et al 1994). The main goals of these meteorological observations were to study meso-scale and planetary-scale systems and processes, to investigate boundary layer phenomena and to obtain a better understanding of the Earth's atmosphere through comparison with that of Mars.…”

Section: Viking Lander Missionsmentioning

confidence: 99%

“…From this sol onward, a VL2 engineering sensor was used for making temperature measurements, with a worst-case reduced accuracy of ±4°C (Hess et al 1977;Sutton et al 1978). Problems with VMIS onboard VL1 started on sol 45 when the heater of the wind direction sensor failed.…”

Section: Viking Lander Missionsmentioning

confidence: 99%

“…In addition, operational modes consisting of extended periods of sampling at 1 Hz were used. Initially, four pressure measurements at 1 Hz were made at the start of every module, but this was later reduced to one sample every 17 min (Hess et al 1977). The data acquisition frequency was reduced towards the end of the landers' lives.…”

Section: Viking Lander Missionsmentioning

confidence: 99%

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The Modern Near-Surface Martian Climate: A Review of In-situ Meteorological Data from Viking to Curiosity

et al. 2017

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We analyze the complete set of in-situ meteorological data obtained from the Viking landers in the 1970s to today's Curiosity rover to review our understanding of the modern near-surface climate of Mars, with focus on the dust, CO 2 and H 2 O cycles and their impact on the radiative and thermodynamic conditions near the surface. In particular, we provide values of the highest confidence possible for atmospheric opacity, atmospheric pressure, near-surface air temperature, ground temperature, near-surface wind speed and direction, and near-surface air relative humidity and water vapor content. Then, we study the diurnal, seasonal and interannual variability of these quantities over a span of more thanThe original version of this article was revised because due to an unfortunate turn of events a wrong value was published in Table 1. The resolution of the PHX pressure sensor was published as "0.1 mbar" whereas this value has now been corrected to "0.1 Pa" which is the correct value and should be regarded as the final version by the reader. B G.M. Martínez

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Section: Viking Lander Missionsmentioning

confidence: 99%

Section: Viking Lander Missionsmentioning

confidence: 99%

Section: Viking Lander Missionsmentioning

confidence: 99%

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The Modern Near-Surface Martian Climate: A Review of In-situ Meteorological Data from Viking to Curiosity

et al. 2017

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“…The images returned by Mariner 9 of the massive outflow channels provided the first indication that large amounts of water once flowed across the surface of Mars [McCauley et al, 1972;Masursky, 1973;Milton, 1973], despite the fact that at current pressures and temperatures liquid water is not stable on the surface [Hess et al, 1977;Kieffer et al, 1977]. While most investigators agree that fluvial processes have operated at some time during Martian history [e.g., Sharp and Malin, 1975;Cart, 1979Cart, , 1996Baker, 1982 Utopia Planitia is a large plain located in the northern lowlands of Mars (Plate 1 a).…”

Section: Introductionmentioning

confidence: 99%

Utopia Basin, Mars: Characterization of topography and morphology and assessment of the origin and evolution of basin internal structure

Thomson¹,

Head²

2001

J. Geophys. Res.

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Abstract. Recently obtained Mars Orbiter Laser Altimeter (MOLA) topography has permitted a new assessment of the morphology, structure, and history of Utopia Planitia. The new topographic data convincingly demonstrate that the Utopia region is an impact basin, as originally proposed by McGill [1989], whose major topographic expression is a circular, 1-3 km deep depression •3200 km in diameter. Utopia Basin is the largest easily recognizable impact structure in the northern hemisphere of Mars and is the only portion of the northern lowlands that exhibits a distinct large-scale impact signature; its presence there and its ancient age verify that a significant part of the northern lowlands dates back to the Noachian period. Using slope maps derived from gridded topography, we have mapped a series of linear slope anomalies within the basin and have analyzed their origin. These features can be classified into two groups: one oriented dominantly radial to the basin and the other oriented dominantly circumferential. The circumferential features are tens of kilometers wide and hundreds of kilometers long and appear to remain relatively constant with respect to elevation. We explore end-member hypotheses (1) that the features formed by the direct action of water/ice or (2) that they are tectonic wrinkle ridges. We interpret the majority of these features to be due to tectonic deformation (primarily wrinkle-ridge formation), modified by later sedimentation associated with the emplacement of the outflow channels and the formation of the Vastitas Borealis Formation. On the basis of the characteristics of these features and their association with polygonal terrain, thumbprint terrain, smoothness of units, and evidence of sedimentary deposits, we find that our results support earlier hypotheses proposing that a significant volume of water occupied Utopia Basin during the late Hesperian period of outflow channel formation. Utopia Basin differs significantly in depth and degradation state from the deeper and fresher-appearing Hellas Basin, although the two are both Noachian in age. A significant part of this difference seems reasonably interpreted to be the result of the extensive sedimentary and volcanic infilling history of the northern lowlands.

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“…The lack of small-scale topographic variability allows the MGCM to represent wind stress as an instantaneous value over 1.5 hours without losing any largescale wind stress fidelity. However, short time period, small scale temporal and spatial gusts may be responsible for transporting a greater amount of sand than predicted; the mean winds measured at Viking Lander I on sol 22 were 2.64 m/s, yet periodic 6-8 m/s gusts were observed [Hess et al, 1977]. Lastly, we use the wind stresses calculated at the lowest level of cells in the MGCM, a height -250 m above the surface, even though this is more than ideal for a surface representation.…”

mentioning

confidence: 99%

Assessing the Martian surface distribution of aeolian sand using a Mars general circulation model

Anderson

Greeley²,

Xu³

et al. 1999

J. Geophys. Res.

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Meteorological results from the surface of Mars: Viking 1 and 2

Cited by 294 publications

References 25 publications

The Modern Near-Surface Martian Climate: A Review of In-situ Meteorological Data from Viking to Curiosity

The Modern Near-Surface Martian Climate: A Review of In-situ Meteorological Data from Viking to Curiosity

Utopia Basin, Mars: Characterization of topography and morphology and assessment of the origin and evolution of basin internal structure

Assessing the Martian surface distribution of aeolian sand using a Mars general circulation model

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