The Pace of Fluvial Meanders on Mars and Implications for the Western Delta Deposits of Jezero Crater

Lapôtre, M. G. A.; Ielpi, Alessandro

doi:10.1029/2019av000141

Cited by 39 publications

(59 citation statements)

References 133 publications

(201 reference statements)

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“…The lower 5% bound on our data of  f I 0.0064 is significantly larger than the values of  0.0001 f I estimated for two local studies on Mars (Buhler et al, 2014;Lapôtre & Ielpi, 2020). These relatively low f I values on Mars could indicate major differences in ancient martian fluvial systems from their terrestrial counterparts-they could represent very low sediment-generation rates and/or high precipitation rates, or they could represent additional sources of intermittency beyond those present on Earth, such as a cold and icy climate with episodic clement climates induced by rare volcanic or impact events (e.g., Segura et al, 2002;Halevy & Head, 2014).…”

Section: Application To Marscontrasting

confidence: 80%

“…The shaded region represents common values for rivers on Earth (

I_{f}

= 0.01–1). Martian values are from (Buhler et al., 2014; Lapôtre & Ielpi, 2020).…”

Section: Resultsmentioning

confidence: 99%

“…Figure 3. (a) Histogram of the number of study locations versus the intermittency factor for our study of terrestrial rivers and deposits, and for deposits on Mars showing the values assumed in previous work and the values calculated for Mars(Buhler et al, 2014;Lapôtre & Ielpi, 2020). (b) Calculated depositional timespan for previously studied Mars deposits using the 5th, 50th, and 95th percentile values of intermittency factors from this study.…”

mentioning

confidence: 90%

See 2 more Smart Citations

Constraining the Timespan of Fluvial Activity From the Intermittency of Sediment Transport on Earth and Mars

Hayden

Lamb

McElroy

2021

Geophysical Research Letters

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Measuring timespans recorded in river deposits is a key goal in better understanding ancient environments on Earth and Mars (Paola et al., 2018). On Mars, using river deposits is particularly useful because most geochronological methods to constrain depositional timespans are unavailable. Moreover, it is unclear whether early Mars had a long-lived, stable hydrological cycle or multiple intermittent, short-lived, river-forming episodes (e.g.,

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Section: Application To Marscontrasting

confidence: 80%

“…The shaded region represents common values for rivers on Earth (

I_{f}

= 0.01–1). Martian values are from (Buhler et al., 2014; Lapôtre & Ielpi, 2020).…”

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 90%

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Constraining the Timespan of Fluvial Activity From the Intermittency of Sediment Transport on Earth and Mars

Hayden

Lamb

McElroy

2021

Geophysical Research Letters

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“…The focus of the Mars program at the beginning of the Spirit and Opportunity rover missions had been to “follow the water.” The discovery of layered bedrock, the presence of spherical Fe-oxide concretions (“blueberries”), and a host of other water/rock features at Meridiani Planum showed that this site was host to several groundwater recharge events (McLennan et al , 2005 ; McLennan, 2012) and had a stagnant paleo-groundwater table for a significant amount of time (Ehlmann et al , 2011 ). Later with the Curiosity rover mission to Gale crater (Hurowitz et al , 2017 ) and the upcoming Perseverance rover mission to Jezero crater (Lapôtre and Ielpi, 2020 ), the shift to habitable environments on Mars has linked the ancient stable surface waters of the late Noachian to areas where sedimentary outcrop could reveal signs of life (Westall et al , 2015 ).…”

Section: Probability Of Life Detections: Moving Toward Life Validationmentioning

confidence: 99%

A Proposed Geobiology-Driven Nomenclature for AstrobiologicalIn SituObservations and Sample Analyses

et al. 2021

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As the exploration of Mars and other worlds for signs of life has increased, the need for a common nomenclature and consensus has become significantly important for proper identification of nonterrestrial/non-Earth biology, biogenic structures, and chemical processes generated from biological processes. The fact that Earth is our single data point for all life, diversity, and evolution means that there is an inherent bias toward life as we know it through our own planet's history. The search for life ''as we don't know it'' then brings this bias forward to decision-making regarding mission instruments and payloads. Understandably, this leads to several top-level scientific, theoretical, and philosophical questions regarding the definition of life and what it means for future life detection missions. How can we decide on how and where to detect known and unknown signs of life with a single biased data point? What features could act as universal biosignatures that support Darwinian evolution in the geological context of nonterrestrial time lines? The purpose of this article is to generate an improved nomenclature for terrestrial features that have mineral/microbial interactions within structures and to confirm which features can only exist from life (biotic), features that are modified by biological processes (biogenic), features that life does not affect (abiotic), and properties that can exist or not regardless of the presence of biology (abiogenic). These four categories are critical in understanding and deciphering future returned samples from Mars, signs of potential extinct/ancient and extant life on Mars, and in situ analyses from ocean worlds to distinguish and separate what physical structures and chemical patterns are due to life and which are not. Moreover, we discuss hypothetical detection and preservation environments for extant and extinct life, respectively. These proposed environments will take into account independent active and ancient in situ detection prospects by using previous planetary exploration studies and discuss the geobiological implications within an astrobiological context.

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“…The instantaneous bankfull discharge estimate could balance evaporation for fluxes up to ∼170–560 m 3 /s. However, bankfull flows occur on roughly yr −1 timescales on Earth and Lapôtre and Ielpi (2020) estimate intermittency for the western delta in Jezero crater ranging between ∼10 −2 and 10 −6 day −1 , with a best fit estimation of ∼10 −4 day −1 , or ∼1 day of flow per decade. Assuming that these same timescales apply to Garu (i.e., ∼1 day of flow per year to ∼1 day of flow per decade), intermittent bankfull surface runoff would be insufficient to sustain a large lake.…”

Section: Discussionmentioning

confidence: 99%

The Hydrogeomorphic History of Garu Crater: Implications and Constraints on the Timing of Large Late‐Stage Lakes in the Gale Crater Region

Putnam

Palucis

2021

JGR Planets

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The Pace of Fluvial Meanders on Mars and Implications for the Western Delta Deposits of Jezero Crater

Cited by 39 publications

References 133 publications

Constraining the Timespan of Fluvial Activity From the Intermittency of Sediment Transport on Earth and Mars

Constraining the Timespan of Fluvial Activity From the Intermittency of Sediment Transport on Earth and Mars

A Proposed Geobiology-Driven Nomenclature for AstrobiologicalIn SituObservations and Sample Analyses

The Hydrogeomorphic History of Garu Crater: Implications and Constraints on the Timing of Large Late‐Stage Lakes in the Gale Crater Region

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