- Email: [email protected]
Mars: Formation and fate of a frozen Hesperian ocean
Accepted Manuscript
Mars: Formation and fate of a frozen Hesperian ocean. Michael Carr , James Head PII: DOI: Reference:
S0019-1035(18)30166-0 https://doi.org/10.1016/j.icarus.2018.08.021 YICAR 12996
To appear in:
Icarus
Received date: Revised date: Accepted date:
16 March 2018 9 July 2018 23 August 2018
Please cite this article as: Michael Carr , James Head , Mars: Formation and fate of a frozen Hesperian ocean., Icarus (2018), doi: https://doi.org/10.1016/j.icarus.2018.08.021
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT 1 Highlights
Successive floods may have caused the accumulation of a frozen ocean over 3 billion years ago. The water was lost to space and to other cold traps such as the polar layered deposits. Past loss rates to space must have been much higher than present rates
AC
CE
PT
ED
M
AN US
CR IP T
ACCEPTED MANUSCRIPT 2
Mars: Formation and fate of a frozen Hesperian ocean.
Corresponding author: Michael Carr Institution: Address: Email:
CR IP T
US Geological Survey 345 Middlefield Rd. [email protected]
Co-author: James Head
AN US
Brown University, Providence, RI 02912, USA
M
1. Introduction
CE
PT
ED
The possibility that the northern plains of Mars could have once contained ocean-sized bodies of water has long been recognized (e.g. Baker et al., 1991; Lucchitta et al., 1986; Parker et al., 1989, 1993). Large outflow channels, widely interpreted as cut by floods, drain into the plains; the plains have low slopes (Kreslavsky and Head, 1999) and roughness (Kreslavsky and Head, 2000) comparable to terrestrial ocean basins; many features on the plains resemble sub-glacial terrestrial landforms and could have formed under a frozen ocean (Kargel et al., 1995); long, continuous breaks in slope surrounding the plains could be shorelines (Parker et al, 1993); widespread fluvial dissection of the highlands may imply an extended water source (see summary in Carr, 2006). More recently, Costard et al. (2016) and Rodriquez et al (2016) have found geomorphic features that they interpret as evidence of impact-generated tsunamis.
AC
The former presence of oceans has been suggested by two main lines of reasoning. First, high erosion rates and widespread valleys and lakes in the cratered highlands suggest that late Noachian Mars could have had a hydrologic cycle with evaporation from an ocean, precipitation on the ancient highlands to form the valley networks and drainage back into the northern lowlands basin (e.g. Baker et al., 1991; Craddock and Maxwell, 1993). Second, a precipitous drop in rates of erosion and valley network formation at the end of the Noachian has been interpreted to indicate that the climate changed from one that was warm and wet, or warm and arid (Craddock and Howard, 2003; Ramirez and Craddock, 2018), to an extremely cold and dry climate more like the present, and that a thick cryosphere developed during the transition (Clifford, 1993; Carr, 1996). Large outflow channels then formed, interpreted to be the result of massive eruption of groundwater trapped below the cryosphere (Carr, 1979; Andrews-Hanna and Phillips, 2007). The channels drained into the northern plains to form large
ACCEPTED MANUSCRIPT 3 sea or ocean-scale bodies of water that would then have frozen in the global cold and arid climate (Kreslavsky and Head, 2002a; Turbet et al., 2017). The size and fate of this later Hesperian-aged iceocean that formed contemporaneously with the outflow channels, according to this hypothesis, is the main concern of this paper. A possible earlier Noachian-aged ocean is mentioned only peripherally.
PT
ED
M
AN US
CR IP T
Almost everything about the proposed Hesperian ocean is controversial (see summary in Head et al., 2018) including the cause, the number, magnitude and timing of the contributing outflow events, whether the water would have quickly frozen so that any standing body of liquid water would have been short-lived, how compelling the evidence for tsunamis is, and where all the water subsequently went. Climatic considerations are a major source of skepticism that there could have been a long-lived liquid ocean in the Hesperian, one that survived long enough to erode topographically identifiable shorelines along its shore and to have experienced impact generated tsunamis. A long-lived, liquid, high-latitude ocean would require near-equatorial temperatures close to 273 K. Partly because of the less-luminous early Sun, greenhouse warming of a thick CO2-H2O atmosphere falls far short of that required to raise the effective surface temperature from the present 215K to in excess of 273K (e.g. Kasting, 1991; Haberle et al., 2017). The supplemental effects of other greenhouse gases, such as SO2, CH4, NH3, H2 and N2O have also been studied, but for a variety of reasons all, either independently or in combination, fail to give the required long-lived boost in temperature (summarized in Haberle et al., 2017). Temporary warming as a consequence of large impacts has also been examined (Segura et al., 2008; Palumbo and Head, 2017; Turbet et al., 2017) but such effects are more likely in the Noachian, when impact rates were much higher, than in the Hesperian. Complete discussion of all the controversies is beyond the scope of this paper. We acknowledge that large amounts of water flowed into the northern plains during large floods but are skeptical that there was a long-lived liquid ocean. Alternatively, we propose that the water from each successive flood rapidly froze to form a layer of ice (Kreslavsky and Head, 2002a, Turbet et al., 2017) and that multiple floods resulted in accumulation of a long-lived, ocean-sized body of ice, but not an ocean-sized body of liquid water. We assume that the ice slowly sublimated as water was lost to space and as changes in obliquity caused redistribution of the water. The formation and fate of this body of ice is the main concern of this paper.
AC
CE
Parker et al. (1989, 1993) and Clifford and Parker (2001) identified several features encircling the northern basin that they interpreted as shorelines of an ocean. The youngest and most easily identifiable of these proposed shorelines (the Utopia shoreline, or contact 2) is closest to an equipotential surface (Head et al., 1999). In order to explore the validity of the Hesperian ocean hypothesis, we interpret this distinctive contact as marking the edge of a frozen ocean, and we assess the implications of this hypothesis. We re-estimate the volume enclosed by this shoreline in light of recent geologic mapping and THEMIS data. We then try to reconcile this ice volume with the present near surface inventory of water. We re-examine the amounts of water that could have been lost to sinks (such as to space and to groundwater), and the amounts gained from sources other than the interpreted ice-ocean. Again, our concern here is exclusively with the youngest and best preserved of the proposed shorelines (Contact 2 or the Deuteronilus shoreline). We recognize that there could have been additional, older shorelines of Noachian age that imply much larger volumes (Clifford and Parker,
ACCEPTED MANUSCRIPT 4 2001), but these are not discussed. We are concerned here exclusively with the volume of the supposed Hesperian ice-ocean and where the water went.
AN US
2. Present inventory of near-surface water.
CR IP T
We use the contrast between the present atmospheric D/H (Villanueva et al., 2015) and the D/H in sediments from Gale Crater (Mahaffy et al., 2015) as one constraint on how the near surface inventory of water may have evolved over time. The age of Gale crater is poorly constrained but crater counts on, and superposition relations of, the sediments in the central mound suggest that they are 3.6-3.8 b.y. old and straddle the Noachian –Hesperian boundary (Thomson et al., 2011). In contrast, the outflow channels and the sediments of the northern plains that were deposited by them are upper Hesperian in age (3 to 3.5 b.y. old) (Tanaka et al. 2005). The sediments at Yellowknife bay in Gale Crater unambiguously accumulate in a lake that may have been long-lived (Grotzinger et al., 2014). Our assumption that the waters from the later outflow channels would rapidly freeze may imply, therefore, a change in surface conditions between the early and late Hesperian, and this may not survive further scrutiny.
CE
PT
ED
M
There is abundant evidence of unbound water near the martian surface, particularly at high latitudes. MOLA topography (Smith et al 1999) and MARSIS and SHARAD data (Plaut et al., 2007; Byrne, 2009) indicate that the layered deposits at the two poles combined contain 17-22 m Global Equivalent Layer (GEL) (Lasue et al., 2013; Carr and Head, 2015). Ground ice has also been detected at latitudes above 600 outside the layered terrains by gamma-ray and neutron spectrometers (Boynton et al., 2002), by ground-penetrating radar (Mouginot et al., 2010), at the Phoenix landing site (Smith et al., 2009), in images of fresh impact craters (Byrne et al., 2009) and in a latitude-dependent mantle derived from mobilization of polar ice during cycles of increased obliquity amplitude (Head et al, 2003) and thought to contain a 7-70 cm thick water global equivalent layer (GEL) today (Kreslavsky and Head 2002b). Ice layers extending from near the surface to depths of 100 m have also been observed in cliffs at latitudes as low as 550 (Dundas et al., 2018). Mouginot et al. (2010) interpret the steep decrease in the 3-5 MHz reflectivity observed by MARSIS at latitudes greater than 500 as due to the presence of ground ice, which at these latitudes is stable a few meters below the surface under present conditions (e.g. Mellon and Jakosky, 1993). Mouginot et al. (2010) estimate that the radar is effectively probing to depths of 6080 m and that at least 106 km3, or 7 m GEL, of ground ice is present outside the polar layered deposits to these depths at latitudes greater than 50 deg.
AC
Near surface ice may be present at even lower latitudes. SHARAD sounding has detected interfaces interpreted as the bases of extensive ice sheets in Utopia and Arcadia Planitiae that extend as far south as 380 (Bramson et al. 2017). Ice may also be present in the 30-50 deg latitude bands in a meters-thick, dust-ice-rich mantle, interpreted to have been deposited during recent obliquity excursions (Head et al., 2003), and in lineated valley fill Head et al., 2010), concentric crater fill (Levy et al, 2010), pedestal craters (Kadish and Head 2014), debris-covered glaciers (Plaut et al, 2009; Holt et al., 2008) and tropical mountain glaciers (Head and Weiss, 2014). Levy et al. (2014) estimate that as much as 2.6 m GEL may be present near the surface in these bands. In summary, we estimate that 20-30 m GEL of water is present in the polar layered deposits and at depths shallower than 80 m in the regions surrounding the
ACCEPTED MANUSCRIPT 5 polar layered deposits extending down to 300 latitude. We recognize that in addition to the 20-30 m GEL of near-surface water, abundant unbound water (possibly hundreds of m GEL) may exist as ice cement and secondary ice within the cryosphere at depths greater than 80 m and as groundwater below the cryosphere (Clifford, 1993). 3. Ocean volume
AN US
CR IP T
Parker et al. (1989; 1993) were the first to suggest that various linear features around the northern basin were shorelines of a former ocean. They identified two contacts, an outer contact 1 and an inner contact 2 around the northern plains that they interpreted as shorelines. Subsequent acquisition of MOLA elevation data (Smith et al., 1998) enabled the ocean hypothesis to be tested more rigorously than had previously been possible. Head et al. (1999) used MOLA altimetry data to test whether the Parker et al. shorelines represented equipotential surfaces, and found that Contact 1 (-1680 m) ranged over 11 km and was, therefore, not likely to be a shoreline. Contact 2 (-3760 m) ranged over 4.7 km, but had extensive stretches that had much less variation and could be consistent with an equipotential surface representing a shoreline.
AC
CE
PT
ED
M
Carr and Head (2003) examined in detail the geologic relations, morphology and elevations of contacts 1 and 2 in light of the MOLA altimetry data and the more precise information on location of the contacts given in Clifford and Parker (2001). They found that some contacts are clearly of volcanic origin and that contact 1, at the boundary between the southern uplands and the northern plains, has a wide spread of elevations and is unlikely to be a shoreline. In agreement with previous work, however, they concluded that large expanses of contact 2 are close to a constant elevation of around -3760 m, and could potentially be consistent with a shoreline. There was, however considerable uncertainty in the exact location of the shorelines and it was not clear how much the spread in elevation was due to the contacts not being ancient shorelines and how much was due to mis-location of the shorelines. The latter problem was particularly acute where the contact was on or close to a steep slope such as along the plains-upland boundary. Carr and Head (2002) concluded that better support for the former presence of water over large parts of the northern plains is provided by the Vastitas Borealis Formation (VBF), an Upper Hesperian thin veneer of material in the central northern lowlands overlying the Lower Hesperian volcanic ridged plains (Tanaka et al., 2005). They found that support for this interpretation came from: 1) the similarity in age between the outflow channels and the VBF, 2) the presence of the VBF at the lower ends of the outflow channels, and 3) identification of numerous features in the outcrop areas of the VBF that are suggestive of basal melting of an ice sheet (Kargel et al., 1995). Publication of the global geologic map of Mars (Tanaka et al., 2014) and the availability of global THEMIS daytime images (http://mars.asu.edu/data/thm_dir_100m/) enables a new assessment of the exact location of the proposed shorelines and, in conjunction with the MOLA data, their elevation. The availability of the geologic map is particularly useful. Identification of geologic units and the depiction of their distribution are based solely on the observed surface characteristics, having been compiled independently of any model for the northern plains or intent to prove or disprove the presence of shorelines. The THEMIS daytime images have proven particularly useful in providing a new source of data that enables better portrayal of contrasts in the textural and thermal properties of the surface,
ACCEPTED MANUSCRIPT 6 distinction between units, and sharper definition of their contacts, thereby reducing the dependence solely on topography for recognizing possible shorelines.
PT
ED
M
AN US
CR IP T
We find that one the most compelling cases for a shoreline is provided by the outer boundary of the Vastitas Borealis Formation (VBF) around the southern and western rim of the Utopia basin, as portrayed in the Tanaka et al. (2014) global geologic map (Figure 1) and in Ivanov et al. (2017). The VBF occurs widely throughout the northern plains. It is characterized by numerous closely spaced low hills, some pitted, and some arrayed in closely spaced curved ridges to form a ‘thumb-print’ texture. Areas of polygonal fractures are common, at different scales and in different locations. Locally in the interior of Utopia, graben-like linear intersecting troughs form complex networks (Heisinger and Head, 2000). A distinctive variety of surface units and textures can be distinguished, assessed stratigraphically and dated using superposed craters (Ivanov et al., 2014, 2015, 2017). Superimposed impact craters commonly have bright halos, thereby giving the unit a mottled appearance (Tanaka et al. 2005). Many of the textures have been attributed to the former presence of a frozen ocean (Kargel et al., 1995; Ivanov et al., 2014, 2015, 2017). The unit is labelled as Late Hesperian on the Tanaka et al. (2014) map but the accompanying correlation chart indicates that the unit may extend down into the Early Hesperian. Kreslavsky and Head (2002a) suggest that the unit is effluent deposited from an ocean (or multiple lakes) that formed contemporaneously with the outflow channels in the Late Hesperian. From the presence of buried ridges and ‘ghost’ craters, they estimated that the unit is approximately 100 m thick. Around the south and west margins of the Utopia basin the outer boundary of the VBF is easily recognizable in the THEMIS daytime mosaics and readily distinguishable from the surrounding units by contrasts in albedo and surface texture (Figure 2). The boundary here has little topographic expression. It closely follows the -3650 m contour for 2800 km around the south and west margins of the Utopia basin (Figure 1). It is difficult to imagine any geologic feature or process, other than a shoreline, that would so closely follow a contour over such large distances, and thus we choose to pursue this interpretation. The precise origin of such a shoreline in southern Utopia is uncertain, however. One possibility is that it marks the furthest reach of the last major flood that entered the northern basin and marks the limit of deposition of effluent from that flood. At the time of the last flood most of the water from the previous floods may have already frozen to form a solidified ice-ocean.
AC
CE
Away from southern Utopia the -3650 m contour as a shoreline is not so compelling (Carr and Head 2002) although its characteristics are not inconsistent with this interpretation. To the east of Utopia Planitia the contour crosses Amazonian volcanics that extend from Elysium down into the northern basin, so any Hesperian or older shoreline that might have been formerly present would now be buried. Similarly, the VBF abuts against younger units in northern Arcadia Planitia and north of Alba Patera. It is not clear how far south the VBF, and hence any potential shoreline, extended into Arcadia Planitia because of the presence of these younger deposits. The -3650 m contour follows the steep outer boundary of the Olympus Mons aureole deposits. This boundary is almost certainly of volcano-tectonic, not marine origin (Carr and Head, 2002), yet would have been a shoreline if present at the same time as the proposed ocean marked by the -3650 m contour. If the outer aureole deposits formed subsequent to the ocean, as is likely (Tanaka et al. 2014), then the deposits would have buried the shoreline of the southern extension of the ocean into Arcadia Planitia. To the west of Utopia Planitia, the contour follows
ACCEPTED MANUSCRIPT 7 the plains/upland boundary, which is much older than the Hesperian, but which would nevertheless have been a shoreline in the Hesperian if an ocean was present up to the -3650 m elevation.
AN US
CR IP T
In Chryse Planitia, into which most of the large outflow channels empty, the -3650 m contour outlines numerous streamlined islands and other breaks in slope such as the plains-upland boundary (Figure 3). Ivanov and Head (2002) used MOLA altimetry data to show that the largest and most prominent outflow channels (Kasei, Maja, Simud, Tiu, Ares and Mawrth) debouch into Chryse Planitia and disappear into the northern lowlands at average elevations that are all within less than ~170 m of a mean elevation of 3742 m, all within 190 m of the elevation of contact 2, over a lateral distance of over 2500 km. They proposed that the distinctive change of channel morphology could be consistent with a rapid loss of stream energy encountered at a base level such as a subaerial/submarine boundary. Contact 2 does not follow the VBF boundary specifically, which is to the north further into the basin. The -3650 m contour here is an erosional boundary rather than what appears to be a depositional boundary in Utopia Planitia. Possible explanations in the context of this interpretation are that late stage floods removed the VBF in Chryse or that the rapidly moving floods entering Chryse Planitia eroded the ocean floor and did not deposit their sediment load until well below the -3650 m contour (Ivanov and Head, 2002).
ED
M
The fate of the water released by the outflow channels and any deposited in an ocean would have depended on the climatic conditions under which it formed. Turbet et al. (2017), using 3-D Global Climate Model simulations, explored the release of water in individual outflow channel events, its fate, and its effect on the climate. They modeled the short and long term climatic impacts of a wide range of outflow channel formation events under cold Mars conditions interpreted to exist in the Late Hesperian, and found that even the most intense (largest, highest flux) of these events cannot trigger long-term greenhouse global warming. In a typical event, the outflow channel water reaches the bottom of the basin in a few days, and freezes over within just a few hundred days. It then sublimates to cold traps at the poles possibly within a few hundred thousand years.
AC
CE
PT
An ocean would clearly have to have accumulated by multiple events as indicated by the number of outflow channels entering the basin. If, as appears likely and as described above, global climate conditions were similar to present conditions and a thick cryosphere was present (required for the overpressurized aquifer origin for the outflow channels), then the body of water that formed after each event would have frozen within a geologically short period of time (103 to 104 years depending on the size of the event; Kreslavsky and Head , 2002a; Turbet et al., 2017). The ice could potentially stabilize and remain between outflow channel events if a sublimation lag was formed rapidly after each event (Kreslavky and Head, 2002; Bramson et al., 2017). Mellon and Jakosky (1995) show, for example, that under conditions expected at an obliquity of 300, ice is stable at all latitudes at depths greater than a 1020 cm. In this specific scenario, repetitive floods could build an ocean-sized body of ice, layer upon layer as each water outflow event built on the frozen, sublimation lag protected, earlier layers. Once the era of flooding ended the ice would slowly sublimate, possibly over hundreds of thousands to millions of years, with the water being both lost to space and redistributed across the martian surface (Figure 4). According to this scenario, the -3650 m shoreline never enclosed an ocean-sized body of liquid water; rather, it marked the edge of the last outflow channel flood that flowed across the northern basin, which at the time would be almost completely filled with ice from the previous floods. For the rest of
ACCEPTED MANUSCRIPT 8 this paper, we will assume this specific scenario, that in the mid-late Hesperian, there was a solidified ice-ocean in the northern plains composed of residual ice layers from the individual outflow channel events. The -3650 m contour, enclosing ~110 m GEL marks the limit of the final flooding event. We will attempt to determine where the 110 m GEL of water went. We saw above that we can account for approximately 20-30 m GEL in currently existing deposits, so that approximately 80-90 m is unaccounted for.
CR IP T
4. Outgassing
AC
CE
PT
ED
M
AN US
In order to know what fraction of the present 30 m near-surface inventory of water has been inherited from the Hesperian we need to know how much has volcanically outgassed since that time. To determine this we used a procedure somewhat similar to that used by Greeley (1987) and Greeley and Schneid (1991). The volume of extrusives was derived from the areas of volcanic units, as depicted on the available geologic maps, coupled with thicknesses derived from the burial of craters; then an assumption was made about the water content of the lavas. Our procedure was as follows. The areas of different volcanic plains units were taken from Table 6 in the brochure accompanying the global geologic map of Tanaka et al. (2014). The thickness was estimated by finding the thickness needed to bury all craters on the underlying unit within the mapping resolution, which was assumed to be 105 km2, on the assumption that if there were more craters than the designated age, then that 105 km2 would have been mapped as the older unit. The number of craters on the different aged buried surfaces was determined from equation 13 and Table III in Ivanov (2001), taking into account protection from cratering by the overlying unit. The surface underlying Amazonian units was assumed to have ND(3.8)N(D) (3.0) craters upon it, where ND(3.8) is the number of craters of diameter (D) that has accumulated on a 3.8 b.y. old surface. Similarly, a surface underlying a Hesperian unit was assumed to have ND(4.0) – N(D) (3.8) craters upon it. Rim heights as a function of diameter were taken from Garvin et al. (2002). The procedure suggests a minimum thickness of 800 m for Hesperian plains units (very similar to the 800-1000 m estimates for the Hesperian ridge plains in the northern lowlands derived by different techniques; Head et al., 2002) and 500 m for Amazonian plains units. In addition, edifice volumes from Plescia (2004) were assumed to have accumulated at a constant rate through the Amazonian and Hesperian. Following this procedure we derive extrusive volumes of 1.21 x 107 km3 for the Amazonian and 1.24 x 107 km3 for the Hesperian. These numbers are smaller than those of Greeley and Schneid (2.6 x 107 and 3.3 x 107 km3) mainly because of the smaller areas depicted as volcanic on the Tanaka et al. (2014), map as compared with earlier maps. Intrusives (probably mostly in the form of dikes; e.g., Head et al., 2006) are not included in the estimates. For estimating the effect of outgassing on D/H (see below) we assume, consistent with these figures, that volcanism has declined exponentially over the last 3.5 b.y and that the cumulative volume, V, over the last t billion years (t = 0 to 3.8) is given by V=2.56e7*(1-exp(-0.83*(3.8-t))). The D/H was assumed to be 1 x SMOW (Standard Mean Ocean Water). A significant problem in estimating the amount of water outgassed is in knowing the amount of water originally present in the magmas and the fraction of this amount that was outgassed to the atmosphere. Estimates of the water contents of the Shergottite parent liquids range from 0.0075 to 2.8% (McCubbin et al., 2012; Usui et al. 2012). Following Greeley (1987) and Greeley and Schneid (1991), we assumed that one wt. percent is outgassed, which gives 5 m GEL for the total amount of water outgassed in the
ACCEPTED MANUSCRIPT 9 Amazonian and Hesperian. A later estimate used 0.5 wt. percent water on the basis of terrestrial data (Craddock and Greeley, 2009). These assumptions, if valid, imply approximately 5 m GEL of the present 30 m inventory was added by volcanism after the end of the Noachian.. 5. Infiltration into the ground.
CR IP T
Clifford (1987, 1993) suggested that, despite the presence of a near-global cryosphere during much of Mars’ history, the planet may have maintained a slow global hydrological cycle as meltwater at the base of the polar layered deposits infiltrated into the groundwater system to create a groundwater mound and cause percolation equatorward under the cryosphere. At low latitudes, the groundwater was episodically returned to the surface as a result of impacts, seepages and eruptions of groundwater, thereby completing the cycle. The proposed circulation is driven by the infiltration of meltwater at the poles. Here we examine the plausibility of melting at the base of the polar deposits in light of recent estimates of the global heat flow as a function of time.
PT
ED
M
AN US
Present estimates of global heat flow are significantly less than when the Clifford model was formulated, and these lower heat flow values make it unlikely that basal melting could occur at the poles during the Amazonian and Hesperian. A model by Stevenson et al. (1983), for example, predicted a present heat flow of 30 mW m-2 for present day Mars and approximately 100 mW m-2 at the Amazonian-Hesperian boundary 3 b.y. ago. In contrast, from the geodynamical response of the lithosphere to the presence of the polar deposits, Phillips et al. (2008) estimate that the present heat flow at the north pole is in the 817 mW m-2 range. In addition, McGovern et al. (2002) and Ruiz et al. (2011) have inferred lithosphere thicknesses and heat flows for a number of regions of Mars from gravity/topography admittance spectra. Estimated heat flow values, while in excess of 40 mW/m2 for most Noachian features, are in the 10 to 40 mW/m2 range for Amazonian and Hesperian features except for the large Tharsis volcanoes which have larger local values (Cassanelli et al., 2015). The lower heat flow estimates have also been compared and reconciled with geochemical models (Ruiz, 2014). The upper limit for heat flow (mW m2 ) as a function of time given in Ruiz (2014) was approximated by H = 14.4 + 5.6t -1.61t2 + 0.8t3
AC
CE
where t is the time before present in billions of years. According to this formulation the heat flow is 14.4 mW/m2 at present and 38 mW/m2 at 3 Ga. For a surface temperature of 150K, a basal temperature of 273K and a thermal conductivity of 2W m-1 K-1 (Clifford, 1987), the polar deposits would have to be over 6 km thick for basal melting 3 b.y. ago, over 9 km thick 2 b.y. ago and over 12 km thick 1 b.y. ago. The present deposits are approximately 3 km thick. We conclude, therefore, that polar basal melting has been unlikely since the Hesperian ocean was present and loss of water though the poles into the groundwater system can be ignored. Basal melting may, however, have been significant during the Noachian when heat flows and possibly surface temperatures were higher. Following earlier work (Harrison and Grimm, 2004; Russell and Head, 2007), Cassanelli et al. (2015) assessed the possibility that snow and ice accumulation on Tharsis could be sufficient to cause basal melting and recharge of the groundwater system. They found, however, that even the heat flow at Tharsis would be insufficient to
ACCEPTED MANUSCRIPT 10 cause significant basal melting and recharge, except under the very localized and volumetrically insignificant volcanic edifice heatpipe/drainpipe situation.
6. Loss of equatorial ice and groundwater to the atmosphere.
CR IP T
Another possibility is that the Hesperian ocean formed under warm climatic conditions before a global cryosphere developed and that some significant fraction of the ocean evaporated, thereby causing precipitation and infiltration into the groundwater system in the surrounding regions. There is, however, little evidence to support such a scenario (Turbet et al., 2017). The outflow channels that are interpreted to have caused the ocean are largely undissected by valley networks as are many plains that clearly pre-date the outflow channels, such as Lunae Planum in the case of Kasei Vallis.
PT
ED
M
AN US
One of the more puzzling aspects of the evolution of near-surface water is the role of the loss of water from the equatorial cryosphere. Under present climatic conditions, ice present at the near-surface at low latitudes will tend to sublimate and be transferred to the atmosphere, thereby causing depletion of the near-surface ground ice (Fanale, 1986; Clifford and Hillel, 1983). The depth of depletion will increase in time at a rate dependent on the properties of the near-surface materials and conditions at the surface, with a particular sensitivity to conditions at different obliquities. This could result in substantial transfer of equatorial ground ice to the polar regions over geologic time. Grimm and Painter (2009), and Grimm et al. (2017) estimate, for example, that approximately 60 m GEL would have been removed from the equatorial regions after the transition to modern cold, dry surface conditions in the early Hesperian, most of the losses having taken place in the first billion years. They assume an abrupt transition at 3 B.Y. ago from an earlier climatic regime that allowed retention of equatorial ice to the “modern” regime under which such ice is unstable. The losses are consistent with the scarcity of nearsurface ice at latitudes less than 50-60 deg. as indicated by neutron spectrometer (Feldman et al., 2004) and MARSIS (Mouginot et al, 2010) data. As we saw above, recycling of water through polar basal melting is unlikely, so the ice removed from the equatorial regions would remain near the surface at high latitudes or be lost to space. The water lost would have had a D/H of the near-surface reservoir at the time of transition, which is assumed to be that of that of the Hesperian aged clays at Gale crater (3 x SMOW) (Mahaffy et al. 2015).
AC
CE
If this reasoning is even approximately valid, it would imply that a significant fraction of the present near-surface inventory of water is derived from equatorial ground ice, not directly from a Hesperian ocean and that we would have to account for the fate not only of the 110 m GEL estimated to have been in the ice-ocean, but also the additional approximately 65 m GEL derived from the equatorial cryosphere. However, initiation of loss of groundwater and ground ice from the equatorial regions probably occurred much earlier than the 3 Ga assumed by Grimm et al. (2017). The transition more likely occurred at the end of the Noachian, 3.8 b.y. go, as indicated by the rapid drop off of the rate of formation of valley networks at that time. Indeed, loss of equatorial groundwater may have been a contributing factor in the subsequent filling of the northern basin both by eruption of groundwater to form the outflow channels and by direct transfer from the equatorial cryosphere to the polar regions through the atmosphere. As a result of these uncertainties we do not include additions from the equatorial cryosphere in our assessment of the fate of the water that formerly filled the northern basin.
ACCEPTED MANUSCRIPT 11 We assume that the equatorial losses, even if they were substantial, occurred earlier than the final phase of filling the northern basin indicated by the Deuteronilus shoreline). 7. Exchange between near-surface ice and the atmosphere and other reservoirs.
AC
CE
PT
ED
M
AN US
CR IP T
The evolution of the D/H of the near-surface water reservoir provides clues concerning the fate of water that formed the ice-ocean. Water in the present atmosphere has a value of 6-7 x SMOW (Owen et al., 1998; Aoki et al. ,2015; Villanueva et al., 2015). The value for the mid-Hesperian is approximately 3 x SMOW (Mahaffy et al., 2015). The main cause of the long-term doubling of the D/H of near-surface water since the mid-Hesperian is losses to space from the upper atmosphere (e.g. Yung et al. 1988). To understand the implications of the D/H measurements, we need to know the size of the water reservoir that is being affected by such losses. We saw above that the bulk of the near-surface inventory of water (17-22 m GEL) is in the polar deposits. Observational evidence and modeling suggest that the polar layered deposits are geologically young and dissipate and re-accumulate on geologically short time scales. Crater counts indicate that the north polar layered deposits (NPLD) are only ~105 years old (Herkenhoff and Plaut, 2002). The south polar layered deposits (SPLD) are much older, ranging from 107 to 108 years (Herkenhoff and Plaut, 2002; Koutnik et al., 2002), but are still late Amazonian in age. Levrard et al. (2007) modelled the exchange of water between the poles and low latitudes using a 3dimensional global climate model. Their results indicate that the NPLD completely dissipated during a period of high (> 30 degrees) obliquities 5-10 Ma ago and that they have been re-accumulating during the last 4 Ma as mean obliquity decreased to the present value of 25 degrees. The NPLD are now in an accumulation phase, hence their young age. Superimposed on this long term trend are smaller oscillations. Most recently, geologically, polar water is thought to have been transferred from the poles to lower latitudes where it formed latitude-dependent, ice-rich mantles (Head et al., 2003); the most recent north polar deposits are likely to be derived from the sublimation of the southern part of the latitude dependent mantle. On longer time scales, but still in the late Amazonian, when mean obliquity exceeded 30 degrees, more widespread equatorward transfer of polar ice is interpreted to have resulted in regional ice deposits in the mid-latitudes, including glaciers, lobate debris aprons (LDA), lineated valley fill (LVF) and concentric crater fill (CCF) (Head et al., 2010; Levy et al., 2014; Kadish and Head, 2014; Madeleine et al., 2009; Fastook and Head, 2014). Tropical mountain glaciers are interpreted to have accumulated when the mean obliquity was ~45 degrees (Head and Marchant, 2003; Forget et al., 2006; Fastook et al., 2008). The south polar deposits are more stable than those in the north but still appear to have exchanged with the atmosphere on geologically short time scales (100 Ma). There is little reason to think that the spin-axis/orbital factors that govern the transfer of ice in the present epoch are different from those operating at other times during the last 3.5 Ga, although their amplitudes will differ (Laskar et al., 2004). The polar layered deposits are likely to have been dissipating and re-accumulating throughout this period, with their D/H increasing as a consequence of losses from the upper atmosphere. It is less clear how well the 10 m GEL of ice deposits peripheral to the pole have exchanged with the atmosphere, but the presence of mid-latitude ice sheets and tropical mountain glaciers during this period means that at least some of the ice in the upper part of the regolith is being mobilized as cold traps migrate. Laskar et al. (2004) estimate that there is a 90% probability that obliquity reached 47 degrees in the last 20 Ma, which would have led to more widespread loss of polar
ACCEPTED MANUSCRIPT 12 ice than occurred during the recent episode when obliquities were mostly in the 30-40 degree range. In summary, it is likely that on a time scale of ~100 Ma, all of the 17-22 m GEL polar ice undergoes exchange with the atmosphere as does much of the 10 m GEL near the surface in the circum-polar regions.
AN US
CR IP T
Based in part on D/H measurements, Kurokawa et al. (2014; 2015) proposed a three-reservoir model for the distribution of water (the atmosphere, a near-surface reservoir exchangeable with the atmosphere and a deeper ground-ice reservoir). The D/H in the atmosphere and near-surface reservoir co-evolve, differing only as a result of the fractionation factor between ice and vapor. The D/H of the deeper ground ice retained the value it had at the time of transition from a hypothesized warm and wet/arid Craddock and Howard, 2002; Ramirez and Craddock, 2018), vertically integrated hydrologic regime around 3.8-4.0 b.y. ago, to the present horizontally stratified regime with a global cryosphere. Kurokawa et al. (2014; 2015) suggest that there could have been slow exchange between the deep ground ice and the near-surface reservoir as a result of infiltration, hydrothermal activity, impacts and diffusion. The exchangeable reservoir is held constant in the model, with losses to space from the exchangeable reservoir being offset by net additions from the underlying reservoir. From meteorite data (Usui et al. 2012), they assume that the deep ground ice has a D/H of 1-2 x SMOW. With these assumptions they estimate that a few tens of meters GEL of water have been lost to space for D/H fractionation factors of 0.016 to 0.11, and a few tens to hundreds of meters GEL for a fractionation factor of 0.33.
AC
CE
PT
ED
M
We assume here a similar model, in which a near-surface reservoir that exchanges with the atmosphere overlies a larger ground-ice reservoir that interacts episodically with the overlying exchangeable reservoir. As water is lost from the exchangeable reservoir, its D/H increases and the losses are replaced by incorporating ice from the underlying reservoir, which retains mid-Hesperian D/H of 3 x SMOW (Mahaffy et al, 2015) . The size of the exchangeable reservoir depends on the time scale of interest. In the present epoch, on a time scale of 103 years, the deeper layers of the NPLD are sealed from the atmosphere and so do not interact with it, but on a time scale of 105 years all the NPLD interact with the atmosphere. On time scales of 108 years, because of excursions to higher obliquities, a larger volume exchanges with the atmosphere. The SPLD are erased and the areas peripheral to the poles exchange with the atmosphere (Levrard, 2007). We are interested here in the long term evolution (3.5 b.y.) and the volume that is exchanging and equilibrating with the atmosphere on time scales of 108 years. We will assume that all the NPLD, all the SPLD, and the ground-ice peripheral to the poles to a depth of 80 m, a total of 20-30m GEL, all interact with the atmosphere on times scales of 108 years, and that this volume has been approximately constant for the last 3.5 b.y. 8. Losses to space.
If the atmosphere has been episodically exchanging with a reservoir of near-surface ground ice, as just discussed, then the high D/H ratio of the atmosphere (and by implication the exchangeable ice reservoir) indicates a substantial loss of hydrogen to space. At present day loss rates the equivalent of only 3.6-25 m GEL of water would have been lost over the last 4.2 b.y. (Jakosky et al., in press). Such a low loss rate is incompatible with the evolution of D/H and the size of exchangeable reservoir as just
ACCEPTED MANUSCRIPT 13 described. If there had been no loss or gain of water between the near-surface exchangeable reservoir and the deeper surface, then the Hesperian and present inventories would be related by the expression IH = IP (Rp/RH)(1/1-f)
CR IP T
where IH and IP are the Hesperian and present near-surface inventories, RH and RP are the Hesperian and present D/H ratios, and f is the fractionation factor (Donahue, 1995). Even in the extremely unlikely case of no deuterium lost to space (f=0), a present inventory of 20-30 m and a doubling of the D/H (see above), would imply that at least 20-30 m has been lost.
M
AN US
As noted by almost all who have addressed the issue of losses to space from the upper atmosphere , the loss rates depend on the long term history of the output of the Sun, particularly in the EUV. Comparisons with nearby stars indicate that in the first few hundred million years the Sun’s EUV output declined from 100’s to 10 times the present value. Gudel (2007) and Gudel and Kasting (2011) estimate that by 3.5 b.y. ago the output had declined to 6 times the present value. Their data on the decline can be approximated by the relationship log E = 0.0647e0.726t where E is the enhancement over present rate and t is the time before the present in billions of years. There are uncertainties concerning the dependence of escape rates for oxygen and hydrogen on the intensity of EUV. We assume here a linear dependence. There is also some uncertainty as to whether the solar ages are exactly equivalent to the martian crater ages. The solar ages assume the Sun’s early history is typical of that of nearby stars and derivation of crater ages depend on crater scaling laws and knowledge on the mix of objects in the early Solar System. Such discrepancies could be significant in view of the rapid fall off in the EUV between 3 and 4 billion years ago.
CE
PT
ED
Higher obliquities may also have caused higher hydrogen loss rates in the past. Mellon and Jakosky (1995) suggested that higher obliquities would result in higher column abundances of water in the atmosphere as more water is transferred from pole to pole with the seasons. Their estimated increases are substantial, with an over two orders of magnitude increase from the present 250 to the average obliquity of 420 over the last 4 b.y. Such increases in the water content of the atmosphere could result in significantly enhanced losses from the upper atmosphere. Mischna and Richardson (2005) suggest, however, that this effect may have been overestimated.
AC
Early estimates of the losses of oxygen to space vary widely from the equivalent of 5-15 m GEL of water (Lammer et al. 2003) to 50-80 m GEL (Kass and Yung, 1995; Luhmann et al., 1992). More recently, Jakosky et al. (2017) estimated oxygen losses from MAVEN measurements of 38Ar/ 36Ar in the upper atmosphere. They conclude that as much as a half a bar of CO2 could have been removed by sputtering through time. They note that if the O lost came from H2O then water losses could have been “substantial”. However, even if most of the O lost was from water, it remains unclear when the water was lost, whether before or after formation of the Deuteronilus shoreline. We are interested here in losses in the last ~3.5 billion years, that is since formation of the Hesperian ice-ocean and much of the “substantial” loss could have taken place before that time. 9. Evolution of D/H.
ACCEPTED MANUSCRIPT 14
CR IP T
For the present and Hesperian inventories of 30 m and 110 m GEL, and D/H values of 6 and 3, equation 1 implies a fractionation factor of 0.46 which is a higher value than most published values (e.g. Krasnapolsky, 2000: Yung et al, 1988). But as we saw above, the near-surface reservoir has not been isolated from the rest of the planet and volcanism has added to the surface inventory. Moreover , the loss of 80 m GEL over the last 3.5 b.y. implies a substantially larger present-day loss rate of hydrogen than the early MAVEN estimates (Jakosky, in press), even taking into account the higher, earlier EUV enhancements.
M
AN US
In order to determine how the mid-Hesperian ice inventory of 110 m GEL with a D/H of 3 x SMOW might have evolved to the present near-surface exchangeable inventory of 20- 30 m GEL with a D/H of 5-7 x SMOW, a spread sheet was constructed which started with the present situation and stepped back in time in 100 m.y. increments. At each step the losses to space were calculated starting with different nominal values for present day loss rates and scaling with time to account for the past higher EUV as described above under Losses to Space. Additions as a result of outgassing were made as also described above, using 1 x SMOW for D/H. The exchangeable volume, nominally 30 m GEL was kept constant by adding from a deeper non-exchangeable reservoir with a D/H of 3 x SMOW in order to replace losses from above. The value of 3 x SMOW is based on the assumption that the nonexchangeable reservoir has been protected from interaction with the atmosphere since the ice ocean was present. With these constraints the fractionation factor that results in evolution of D/H of the exchangeable reservoir from 3 x SMOW at 3.5 b.y. ago to the present value of 5-7 was determined by trial and error. Typical results are shown in Figure 5.
CE
PT
ED
Assuming a present inventory of 30 m GEL of which 4 m is derived from outgassing, then 84 m GEL must be lost to space to eliminate the 110 m GEL estimated to have been in the Hesperian ocean. Present loss rates of 4-25 m GEL in 4.2 b.y. (Jakosky, 2016) fall well short of the required rates even correcting for the earlier higher EUV fluxes . A present day loss of 25 m GEL in 4.2 b.y. implies a loss of 42 m GEL in 3.5 b.y., or half the required loss, even taking into account the higher earlier EUV fluxes. In addition, doubling of the D/H since the mid Hesperian requires present day loss rate of at least 21 m GEL in 4.2 b.y. , that required in the unlikely event of no losses of deuterium since the mid-Hesperian (figure 6). In order to lose the 84 m GEL to space estimated to be required to eliminate the 110 m GEL ocean, we estimate that a present day loss rate of 49 m GEL in 4.2 b.y. is required, almost double the measured rate.
AC
One possibility for the shortfall is that the losses to space have been underestimated. This could occur because the measured rates are not typical of the present epoch, because the effects of the early EUV enhancements were underestimated or because possible higher loss rates during periods of high obliquity were not taken into account. Another possibility is that the present near-surface inventory has been underestimated. Mouginot et al. (2010) acknowledge that their estimate from MARSIS of 7 m GEL outside the polar caps at depths less than 60-80 m is a lower limit. We argued above that significant amounts of water sublimated from the ice-ocean could not have re-entered the groundwater system because of the presence of a thick cryosphere. If true, the missing volume, if not lost to space, must be near the surface. It must also be outside the -3650 m contour that defines the 110 m volume of the basin and at latitudes greater than 300 because of stability constraints. Since the basin occupies most
ACCEPTED MANUSCRIPT 15
CR IP T
of the northern hemisphere at latitudes greater than 300, the missing volume, if still present, is most likely at high southern latitudes. Consistent with this conclusion, seven of the eight cliffs in which layers of ice have been observed are in the 55-600 S. latitude band (Dundas et al., 2018). The southern latitudes in excess of 300 constitute only one quarter of the planet’s surface area so to accommodate the missing 30-55 m the southern high latitudes would have to typically be underlain by 120-220 m of ice. While this seems an improbably large amount, the ice layers observed by Dundas et al. (2018) are tens of meters to over 100 m thick so that the high southern latitudes could contain a significant fraction of the missing volume. 10. Conclusions.
AC
CE
PT
ED
M
AN US
1. In the mid to late Hesperian, floodwaters repeatedly flowed into the northern basin under climatic conditions that resemble those of the present day. We assume that each flood froze in a geologically short period of time to form an ice layer that remained there until the next flood. Successive ice layers accumulated to form an ocean-sized body of ice that filled the basin up to the -3650 m contour thereby enclosing 110 m GEL of water. 2. Subsequent to the filling of the basin the ice slowly sublimated into the atmosphere to be lost to space or to accumulate in various near-surface cold traps such as the polar layered deposits. 3. Only minor amounts of water were lost from the surface to the global groundwater system because of the thick cryosphere and low heat flow values. The minor amounts lost were in places where anomalously high heat flow values prevailed as in active volcanic edifice regions. 4. 20-30 m GEL of water are estimated to be near the surface today and exchanging with the atmosphere on geologic time scales. This includes the polar layered deposits and deposits elsewhere at depths less than approximately 80 m. A non-exchangeable reservoir of unknown capacity underlies the exchangeable reservoir. 5. Approximately 5 m of water has been outgassed to the surface since the mid Hesperian. 6. Present day loss rates to space fall far short of those needed to eliminate the volume of the mid Hesperian ice ocean and those needed to cause a doubling of the D/H of the exchangeable reservoir since the mid Hesperian. Earlier loss rates must have been higher. Assuming a linear increase in loss rates because of the higher EUV output of the Sun, a 30 m present inventory, and the upper limit on present loss rates from MAVEN, 42 m GEL of water remain to be accounted for. Possibilities include greater dependence of losses of EUV than assumed and enhanced losses during periods of high obliquity. In addition, large volumes of ice may be present near the surface at high southern latitudes as indicated by recent discoveries of ice layers in cliffs.
Acknowledgements. The paper was improved substantially following comments from attendees at the 4th Early Mars Conference, Flagstaff, Oct 1-6, 2017 and by thoughtful reviews by R. Irwin and an anonymous reviewer. JWH gratefully acknowledges support for participation in the Mars Express High-Resolution Stereo Camera (HRSC) team (JPL 1237163).
REFERENCES
ACCEPTED MANUSCRIPT 16
AC
CE
PT
ED
M
AN US
CR IP T
Andrews-Hanna, J.C., Phillips, R.J., 2007. Hydrological modeling of outflow channels and chaos regions on Mars. J. Geophys. Res. Planets, 112, E08001. https://doi.org/ 10.1029/2006JE002881. Aoki, S., Nakagawa, H., Sagawa, H., Gierann, M., Sindoni. G., Aronica, A. and Kasaba, A., 2015. Seasonal variation of the HDO/H2O ration in the atmosphere of Mars at the middle of northern spring and beginning of northern summer. Icarus, 260, 7-22. Baker, V. R., Strom, R. G., Gulick, V. C., Kargel, J. S., Komatsu, G. and Kale, V. S., 1991. Ancient oceans, ice sheets and the hydrologic cycle on Mars. Nature, 352, 589-59. Boynton, W. V. and 24 colleagues, 2002. Distribution of hydrogen in the near-surface of Mars: Evidence for subsurface ice deposits. Science, 296, 81-85. Bramson, A. M., Byrne, S. and Bapst, J., 2017. Preservation of mid-latitude ice sheets on Mars. J. Geophys. Res., 122, 2250-2260. DOI: 10.1002/2017JE005357. Byrne, S., and 18 colleagues, 2009. Distribution of mid-latitude ground ice on Mars from impact craters. Science, 325, 1674-1676. DOI: 10.1126/science.1175307 Byrne, S., 2009. The polar deposits of Mars. Ann. Rev. Earth Planet. Sci., 37, 535-560, doi: 10.1146/annurev.earth.031208.100101. Carr, M. H., 1979, Formation of martian flood features by release of water from confined aquifers. Jour. Geophys. Res., 84, p. 2995-3007. Carr, M. H., 1996. Water on Mars. Oxford Press, New York Carr, M. H., 2006. The Surface of Mars. Cambridge University Press, Cambridge. Carr, M. H. and Head, J. W., 2002. Oceans on Mars: An assessment of the observational evidence and possible fate. JGR, 108, E5, doi10.1029/2002JE001963. Carr, M. H., and Head J. W., 2015. Martian surface/near-surface water inventory: Sources, sinks, and changes with time. Geophys. Res. Lett., 42, 726-732. Cassanellii, J. P., and Head, J. W., 2016. Lava heating and loading of ice sheets on early Mars: Predictions for meltwater generation, groundwater recharge, and resulting landforms. Icarus, 271, 237-264, doi: 10.1016/j.icarus.2016.02.004. Cassanellii, J. P., and Head, J. W., 2018a. Formation of outflow channels on Mars: Testing the origin of Reull Vallis in Hesperia Planum by large-scale lava-ice interactions and top-down melting. Icarus, 305, 56-79, doi: 10.1016/j.icarus.2018.01.001. Cassanellii, J. P., and Head, J. W., 2018b. Large-scale lava-ice interactions on Mars: Investigating its role during Late Amazonian Central Elysium Planitia volcanism and the formation of Athabasca Valles. Planetary and Space Science, 158, 96-109.Cassanelli, J. P., Head, J. W., and Fastook, J. L., 2015. Sources of water for the outflow channels on Mars: Implications of the Late Noachian "icy highlands" model for melting and groundwater recharge on the Tharsis rise. Planet. Space Sci., 108, 54-65, doi: 10.1016/j.pss.2015.01.002. Citron, R. I., Manga, M., and Hemenway, J., 2018. Timing of oceans on Mars from shoreline deformation. Nature, 55, 643-646. Clifford, S. M., 1987. Polar basal melting on Mars. J. Geophys. Res., 92, 9135-9152. Clifford, S. M. 1993. A model for the hydrologic and climatic behavior of water on Mars, J. Geophys. Res., 98(E6), 10,973–11,016, doi:10.1029/93JE0022. Clifford, S. M. and Hillel, D., 1983. The stability of ground ice in the equatorial region of Mars. J. Geophys. Res. 88, 2456-2474, doi:10.1029/LB088iB03p02456. Clifford, S. M. and Parker, T. J., 2001. The evolution of the martian hydrosphere: Implications for the fate of a primordial ocean and the current state of the northern plains. Icarus, 154, 40-79. Costard, F., Séjourné, A., Kelfoun, K., Clifford, S., Lavigne, F., Di Pietro, I., and Bouley, S., 2017. Modeling tsunami propagation and the emplacement of thumbprint terrain in an early Mars ocean. J. Geophys. Res., 122, 633-649.
ACCEPTED MANUSCRIPT 17
AC
CE
PT
ED
M
AN US
CR IP T
Craddock, R. A. and Maxwell. A. D., 2002. The case for rainfall on a warm, wet early Mars. J. Geophys. Res., 98, 3453-3468. Craddock, R. A. and Greeley, R., 2009. Minimum estimates of the amount and timing of gases released into the martian atmosphere from volcanic eruptions. Icarus, 204, 512-526. Dundas, C. M. and 12 colleagues, 2018. Exposed surface ice sheets in the Martian mid-latitudes. Science, 359, 199-201. DOI: 10.1126/science.aao1619. Fanale, F. P., Salvail, J. R., Zent, A. P., and Postawko, S. E., 1986. Global distribution and migration of subsurface ice on Mars. Icarus, 67, 1-18. Fastook, J. L. and Head, J. W., 2014. Amazonian mid- to high-latitude glaciation on Mars: Supply-limited ice sources, ice accumulation patterns, and concentric crater fill glacial flow and ice sequestration. Planet. Space Sci., 91, 60-76, doi: 10.1016/j.pss.2013.12.002. Fastook, J. L., Head, J. W. and Forget, F., 2008. Tropical mountain glaciers on Mars: Altitude-dependence of ice accumulation, accumulation conditions, formation times, glacier dynamics, and implications for planetary spin-axis/orbital history. Icarus, 198, 305-317, doi:10.1016/j.icarus.2008.08.008. Feldman, W. C. and 15 colleagues, 2004. The global distribution of near surface hydrogen on Mars. J. Geophys. Res.109 (E9) doi:10.1029/2003LE02160. Garvin, J. B., Sakimoto, S.E. H., Frawley, J. J. and Schnetzler, S., 2002. Global geometric properties of martian impact craters. LPSC XXXIII, Abstract 1255. Greeley, R., 1987. Release of juvenile water on Mars: Estimated amounts and timing associated with volcanism. Science, 236, 1653-1654. Greelely, R., and Schneid, B. D., 1991. Magma generation on Mars: Amounts, rates and comparisons with Earth, Moon and Venus. Science, 254, 996-998. Grimm, R. E., and Painter, S. L., 2009. On the secular evolution of groundwater on Mars. Geophys. Res. Lett., 36, L24803, doi:10.1029/2009GL041018. Grimm, R. E., 2017. On the secular retention of groundwater and ice On Mars. J. Geophys. Res., 122, 94-109. doi: 10.1002/2016JE005132. Grotzinger, J. P., and 71 others, 2014. A habitable fluvio-lacustrine environment at Yallowknife Bay, Gale Crater, Mars. Science, 343, 1242777. Harrison, K.P., Grimm, R.E., 2004. Tharsis recharge: a source of groundwater for Martian outflow channels. Geophys. Res. Lett. 31, L14703. doi:10.1029/2004GL020502. Herkenhoff, K. E. and Plaut, J.J., 2002. Surface ages and the resurface rates of the polar deposits on Mars. Icarus, 144, 243-253. Haberle, R. M., Catling, D. C., Carr, M. H. and Zahnle, K.J. 2017. The early Mars climate system, in Haberle, R. M., Clancy, R. T, Forge, F., Smith, M. D. and Zurek, R. W. (Eds.), The atmosphere and climate of Mars, Cambridge Press, 526-568. Head, J. W., Hiesinger, H., Ivanov, M. A. , Kreslavsky, M. A., Pratt, S., and Thomson, B. J., 1999. Possible ancient oceans on Mars: Evidence from Mars Orbiter Laser Altimeter data. Science, 286, 21342137. Head, J. W., Kreslavsky, M. A. & Pratt, S., 2002. Northern lowlands of Mars: evidence for widespread volcanic flooding and tectonic deformation in the Hesperian period. J. Geophys. Res. 107, 5003. doi:10.1029/2000JE001445. Head, J. W. and Marchant, 2003. Cold-based mountain glaciers on Mars: Western Arsia Mons. Geology,31 (7), 641-644. Head, J. W. and Weiss, D. K. (2014) Preservation of ancient ice at Pavonis and Arsia Mons: Tropical mountain glacier deposits on Mars. Planet. Space Sci., 103, 331-338, doi: 10.1016/j.pss.2014.09.004. Head, J. W., Mustard, J. F., Kreslavsky, M.A., Milliken, R. E., and D. R. Marchant, 2003. Recent ice ages on Mars. Nature, 426, 797-802.
ACCEPTED MANUSCRIPT 18
AC
CE
PT
ED
M
AN US
CR IP T
Head, J. W., Marchant, D. R., Dickson, J. J., Kress, A. M. and Baker, D. M. 2010. Northern mid-latitude glaciation in the Late Amazonian period of Mars: Criteria for the recognition of debris-covered glacier and valley glacier land system deposits, Earth Planet. Sci. Lett., 294, 306-320, doi: 10.1016/j.epsl.2009.06.041. Head, J. W., Forget, F., Turbet, M., Cassanelli, J. and Palumbo, A., 2018. Two oceans on Mars? History, problems and prospects. LPSC 49 Abstract #2194. Herkenhoff, K. E. and Plaut, J. J.,2000. Surface ages and resurfacing rates of the polar layered deposits on Mars. Icarus 144, 243-253, doi:10.1006/icar.199.6287 Heisinger, H., and Head, J. W., 2000. Characteristics and origin of polygonal terrain in southern Utopia Planitia,Mars: Results from Mars Orbiter Laser Altimeter and Mars Orbiter Camera data. J. Geophys. Res., 105 (E5), 11,999-12,022. Ivanov, A. B.., 2001. Mars/Moon cratering rate ratio estimates, in Kallenbach, R., Geiss, J., and Hartmann (eds.), Chronology and Evolution of Mars , Kluwer, Dordrecht, 97-104. Ivanov, M. A., Heisinger, H., Erkeling, H., and Reiss, R., 2015. Evidence for large reservoirs of water/mud in Utopia and Acidalia Planitiae on Mars. Icarus 248, 383-391. Ivanov, M. A., Heisinger, H., Erkeling, H., and Reiss, R., 2014. Mud volcanism and morphology of impact craters in Utopia Planitia on Mars: Evidence for the ancient ocean. Icarus, 228, 121-140. Ivanov, M. A., Erkeling, G., Hiesinger, H., Bernhardt, H., Reiss, D.,2017. Topography of the Deuteronilus contact on Mars: Evidence for an ancient water/mud ocean and long-wavelength topography readjustments. Planetary and Space Science 144, 49-70. Kadish, S. H. and Head, J. W., 2014. The ages of pedestal craters on Mars: Evidence for a late-Amazonian extended period of episodic emplacement of decameters-thick mid-latitude ice deposits. Planet. Space Sci., 91, 91-100, doi: 10.1016/j.pss.2013.12.003. Jakosky, B. M., 2016. MAVEN observations of Mars atmospheric loss and implications for long term evolution. Fall AGU meeting, San Francisco, December, 2016. Jakosky, B. M., 2017. MAVEN observations of the Mars upper atmosphere, ionosphere, and solar wind interactions. J. Geophys. Res., Space Physics, 122, 9552-9553, DOI: 10.1002/2017JA024324 Jakosky, B. M., Slipski, M., Benna, M., Mahaffy, P., Yelle, R., Stone, S., and Alsaeed, M., 2017. Mars’ atmospheric history derived from upper-atmosphere measurements of 38Ar/ 36Ar, Science355, 1408-1410. Jakosky, B. M. and 120 colleagues, (in press). Loss of the Martian atmosphere to space: Present-day loss rates determined from MAVEN observations and integrated loss through time. Icarus, www.sciencedirect.com/science/article/pii/S0019103517306917?via%3Dihub. Kargel, J. S., Baker, V. R., Beget, J. E., Lockwood, J. F., Pewe, T. L., Shaw, J. S. and Strom, R. G., 1995. Evidence of ancient continental glaciation in the martian northern plains. J. Geophys. Res., 100, 5351-5368. Kass, D. M., and Yung, Y. L.,1995. Loss of atmosphere from Mars due to solar wind induced sputtering. Science, 268, 697-699. Kasting, J. F., 1991. CO2 condensation and the climate of early Mars. Icarus, 94, 1-13. Koutnik, M., Byrne, S. and Murray, B., 2002. South polar layered deposits of Mars. J. Geophys. Res, 107, E11, 5100, doi:10.1029/2001JE001805. Krasnopolsky, V. (2000), NOTE: On the deuterium abundance on Mars and some related problems. Icarus, 148, 597-602. Kreslavsky, M. A., and Head. J. W., 2000. Kilometer-scale roughness of Mars: Results from MOLA data analysis. J. Geophys. Res., 105 (E11), 26,695-26,711. Kreslavsky, M.A., and Head, J. W., 2002a. Fate of outflow channel effluents in the northern lowlands of Mars: The Vastitas Borealis Formation as a sublimation residue from frozen, ponded bodies of water. J. Geophys. Res., 107, E12, doi:10.1029/2001JE001831.
ACCEPTED MANUSCRIPT 19
AC
CE
PT
ED
M
AN US
CR IP T
Kreslavsky, M.A., and Head, J. W., 2002b. Mars: Nature and evolution of young latitude-dependent water-ice-rich mantle, Geophys. Res. Lett., 29 (15), 1719, doi:10.1029/2002GL015392. Kurokawa. H., Sato, M., Ushioda, M., Matsuyama. T. , Morikawa, R., and Dohm J., 2014. Evolution of water reservoirs on Mars: Constraints from hydrogen isotopes in martian meteorites. Earth and Planet Sci. Lett., 394, 179-0185. Kurokawa, H., Usui, T., and Sato, M, 2016. Interactive evolution of multiple water-ice reservoirs on Mars: insights from hydrogen isotope compositions. Geochem. J., 50, 67–79. Laskar, J., Correia, A. C. M.,Gastineau, M., Joutel, F. , Levrard, B. and Robutel ,P.,2004. Long term evolution and chaotic diffusion of the insolation quantities of Mars. Icarus, 170, 343–364. Lammer, H., Lichtenegger, H. Kolb, C., Ribas, J., GuinanE., Anart, R., and Bauer, S.,2003. Loss of water from Mars: Implications or the oxidation of the soil. Icarus, 165, 9-25. Lasue, J., Mangold, N., Hauber, E., Clifford, S., Feldman, W., Gasnault. O., Grima. C., Sylvestre, M., and Mousis, O. , 2013. Quantitative Assessments of the Martian Hydrosphere. Space Sci. Rev. 174, 155-212. Levrard, B., F. Forget, F. Montmessin, and J. Laskar, 2004. Recent ice-rich deposits formed at highlatitudes on Mars by sublimation of unstable equatorial ice during low obliquity. Nature, 431, 1072–1075. Levrard, B., Forget, F., Montmessin, F and Laskar J. 2007. Recent formation and evolution of the martian polar layered deposits as inferred from a global climate model. J. Geophys. Res. , 112, DOI: 10.1029/2006JE002772. Levy, J., Head, J. W., and Marchant, D. R. 2014. Concentric crater fill in the northern mid-latitudes of Mars: Formation processes and relationships to similar landforms of glacial origin. Icarus, 209, 390-404, doi:10.1016/j.icarus.2010.03.036. Levy, J., Fassett, C. I. , Head, J. W., Schwartz, C. and Watters, J. L., 2014. Sequestered glacial ice contribution to the global martian water budget: Geometric constraints on the volume of remnant, midlatitude debris-covered glaciers. J. Geophys. Res., DOI: 10.1002/2014JE004685. Lucchitta, B. K., Ferguson, H. M. and Summers, C. 1986. Sedimentary deposits in the northern lowland plains, Mars. Proc. 17th Lunar. Planet. Sci. Conf, J. Geophys. Res., 91, E166-E174. Luhmann, J. G., Johnson, R. E. and Zhang, M. G., 1992. Evolutionary impact of sputtering of the martian atmosphere by O+ pick up ions. Geophys. Res. Lett., 19, 2151-2154. Mahaffy, P. R., and 27 colleagues, 2015. Mars atmosphere. The imprint of atmospheric evolution in the D/H of Hesperian clay minerals on Mars. Science, 347, 412-414, doi: 10.1126/science.1260291. Madeleine, J.B. Forget, F., Head, J. W., Levrard, B., Montmessin, F., and Millour, E. 2009. Amazonian northern mid-latitude glaciation on Mars: a proposed climate scenario. Icarus, 203 (2009), pp. 390-405, 10.1016/j.icarus.2009.04.037. McCubbin, F. M., Hauri, E. H., Elardo, S. M., Kaaded, K. V., Wang, J. and Shearer, C. K., 2012. Hydrous melting of the martian mantle produced both depleted and enriched shergottites. Geology, 40, 683-686. doi:10.1130/G33242.1. McGovern, P. J., Solomon, S. C., Smith, D. E., Zuber, M. T., Simons, M., Wieczorek, M. A., et al, 2002. Localized gravity/topography admittance and correlation spectra on Mars: Implications for regional and global evolution. J. Geophys. Res., 107, E12, doi:10.1029/2002JE001854. Mellon, M., and Jakosky, B. M., 1995. The distribution and behavior of martian ground ice during past and present epochs. J. Geophys. Res., 111, 11781-11799. Mouginot, J., A. Pommerol, W. Kofman, P. Beck, B. Schmitt, A. Herique, C. Grima, A. Safaeinili and J. Plaut, 2010. The 3-5 MHz global reflectivity map of Mars by MARSIS/Mars Express: implications for the current inventory of subsurface H2O. Icarus 210, 612-625. Doi: 10.1016/j.icarus 2010.07.003.
ACCEPTED MANUSCRIPT 20
AC
CE
PT
ED
M
AN US
CR IP T
Owen, T., Maillard, J. P., de Berg, C and Lutz, B. L., 1988. Deuterium on Mars: The abundance of HDO and the value of D/H. Science, 240, 1767-1770. Palumbo, A. M., and Head, J. W., 2017. Impact cratering as a cause of climate change, surface alteration, and resurfacing during the early history of Mars. Meteoritics & Planetary Science, in press, doi: 10.1111/maps.13001. Parker, T. J., Saunders, R. S., and Schneeberger, D. M., 1989. Transitional morphology in the west Deuteronilus Mensae region of Mars: Implications for modification of the lowland/upland boundary. Icarus, 82, 111-145. Parker, T. J., Gorsline, D. S., Saunders, R. S., Pieri, D., and Schneeberger, D. M., 1993. Coastal geomorphology of the martian northern plains. J. Geophys. Res., 98, 11,061-11,078. Phillips, R. J., and 24 colleagues, 2008. Mars north polar deposits: stratigraphy, age, and geodynamical response. Science, 320, no. 5880, 1182–1185, http://dx.doi.org/10.1126/science.1157546. Plaut, J. J. and 24 colleagues, 2007. Subsurface radar sounding of the south polar layered deposits of Mars. Science, 316, 92-9. DOI: 10.1126/science.1139672. Plaut, J. J., Safaeinili, A., Holt, J. W., Phillips, R. J., Head, J. W., Seu, R., Putzig, N. E., and Frigeri, A.,2009. Radar evidence for ice in lobate debris aprons in the mid-northern latitudes of Mars. Geophys. Res. Lett., 36, L2203, doi: 10.1029/2008GL036379. Ramirez, R. M., and Craddock, R, A., 2018. The geological and climatological case for a warmer and wetter early Mars. Nature Geoscience 11, 230-237, doi.org/10.1038/s41561-018-0093-9. Rodriguez, J. A., Fairen, A. G., Tanaka, K. L., Zarroca, M., Linares, R., Platz, T., Komatsu, G., Miyamoto, H., Kargel, J. S., Yan, J., Gulick, V., Higuchi, K., Baker, V.R. and Glines, N. (2016). Tsunami waves extensively resurfaced the shorelines of an early Martian ocean. Scientific Report s, Article 25106. Ruiz, J., 2014. The early heat loss evolution of Mars and their implicaitons for internal and environmental history. Scientific Reports 4, Article 4338. doi:10.1038/srep04338. Ruiz, J., McGovern, P, Jimenez-Diaz , A., Lopez , V., Williams, J., Hahn, B., and Tejero , R., 2011. The thermal evolution of Mars as constrained by paleo-heat flows. Icarus, 215, 508-517. Russell, P.S., Head, J.W., 2007. The Martian hydrologic system: multiple recharge centers at large volcanic provinces and the contribution of snowmelt to outflow channel activity. Planet. Space Sci. Planet Mars II, 55, 315–332. doi:10.1016/j.pss.2006.03.010. Segura, T. L., Toon, O. B. and Colaprete, A. 2008. Modeling the environmental effects of moderate-sized impacts on Mars. J. Geophys. Res., 113, doi:10.1029.2008/JE003147. Seu, R., Kempf, S. D., Choudhary, P., Young, D. A., Putzig, N. E., Biccari, D., and Gim, Y., 2008. Radar sounding evidence for buried glaciers in the southern mid-latitudes of Mars. Science, 322, 12351238, doi: 10.1126/science.1164246. Smith, D. E., Zuber, M. T., Frey, H. V., Garvin, J. B., Head, J. W., Muhleman, D. O., Pettengill, G. H., Phillips, R. J., Solomon, S. C., Zwally, H. J., Banerdt, W. B. and Duxbury, T. C., 1998. Topography of the northern hemisphere of Mars from the Mars Orbiter Laser Altimeter,. Science, 279, 16861692. Smith, D. E. and 19 colleagues, 1999. The global topography of Mars and implications for surface evolution. Science 286, 94-97. doi: 10.1126/science.284.5419.1495. Smith, P.H. and 36 colleagues,2009. H2O at the Phoenix landing site. Science, 325, 58-61. doi: 10.1126/science.1172339. Stevenson, D. J., Spohn. T. and Schubert, G.,1983. Magnetism and thermal evolution of the terrestrial planets. Icarus, 54, 466-489. Tanaka, K.L., Skinner, J. A., Dohm, J. M., Rossman, P. I., Kolb, E. J., Fortezzo, C. M., Platz, T., Gregory, G. M. and Hare, T. M.,2014. Geologic Map of Mars. U. S. Geol. Survey, Scientific Inv. Map 3292.
ACCEPTED MANUSCRIPT 21
AN US
CR IP T
Tanaka, K. L., Skinner, J. A., and Hare, T. N., 2005. Geologic map of the northern plains of Mars. U. S. Geol. Survey, Scientific Inv. Map 2888. Thompson, B. J. and 7 others, 2011. Constraints on the origin and evolution of the central mound in Gale Crater using Mars Reconnaisance Orbiter data. Icarus, 214, 413-432. Turbet, M., Forget, F., Head, J. W., and Wordsworth, R., 2017. 3D modelling of the climatic impact of outflow channel formation events on early Mars. Icarus, 288, 10-36, doi: 10.1016/j.icarus.2017.01.024. Usui, T., C. Alexander, J. Wang, J. I. Simon and J. H. Jones, 2012. Origin of water and mantle-crust interactions on Mars inferred from the hydrogen isotopes and volatile elements of olivine-hosted melt inclusions of primitive shergottites. Earth Planet. Sci. Lett., 357-358, 119129. DOI:10.1016/j.epsl.2012.09.008. Villanueva, G.I., , Mumma, M. J., Novak, R. E., Kaufl, H. U., hartogh, P., Emcrenaz, T., Tokunaga, A., Khayat, A., and Smith A. D. , 2015. Strong wter isotopic anomalies in the martian atmosphere: Probing current and ancient reservoirs. Science, 348, 218-221. Yung, Y.L., Wen, J. S., Pinto, J. P., Pierce, K.K., Allen, M. and Paulson, S.,1988. HDO in the martian atmosphere: Implications for the abundance of crustal water. Icarus, 76, 146-159. Zuber, M. T., and 15 colleagues, 2000. Internal structure and early thermal evolution of Mars from Mars Global Surveyor. Science, 287, 1788-1799.
AC
CE
PT
ED
M
Figures.
ACCEPTED MANUSCRIPT
CE
PT
ED
M
AN US
CR IP T
22
Figure 1. Section of the Tanaka et al. (2014) geologic map of the northern hemisphere with the -3650 m
AC
contour superimposed (sinuous black line). The contour mostly follows the outer boundary of the Vastitas Borealis Formation (VBF). Where the contour is colored red, as northwest of Elysium and in Arcadia Planitia, the boundary is buried by younger units.
ACCEPTED MANUSCRIPT
AN US
CR IP T
23
M
Figure 2. The outer contact of the Vastitas Borealis Formation at 20N, 120E. The sharp, easily
AC
CE
PT
ED
recognizable contact can be traced at a constant elevation for well over 2000 km. The VBF is in the upper half of the image. Its southern boundary is marked by small convex outward lobes, interpreted here as a depositional boundary formed by the last major flood that entered the basin. The prominent crater in the lower left is 17 km across (THEMIS day).
ACCEPTED MANUSCRIPT
AN US
CR IP T
24
AC
CE
PT
ED
M
Figure 3. The Chryse basin between 300-360 deg. E and 10-50 deg. N. The -3650 m contour around the basin traces numerous sharp breaks in slope between the uplands and the plains and around islands in the flooded areas. The contour here follows erosional features cut by the large floods entering the basin from the south and west. The VBF boundary is further to the northeast (MOLA).
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
M
AN US
CR IP T
25
ACCEPTED MANUSCRIPT 26
AC
CE
PT
ED
M
AN US
CR IP T
Figure 4. Schematic diagram showing the proposed scenario for formation and elimination of the Hesperian ice ocean. Top: Floods that cut the large outflow channels enter the northern basin and form temporary lakes that rapidly freeze. Successive floods build a sequence of ice layers up to the -3650 contour which marks the edge of the last large flood. Bottom: After the flooding era the ice slowly sublimates, some being lost to space and some being redistributed to form the polar layered deposits and other near-surface ice deposits.
Figure 5. Typical result of modeling the evolution of D/H as described in the text. Here the exchangeable inventory is 30 m GEL and the present day loss rate is 30 m. GEL in 4 b.y. Curves for two different values of the present polar D/H show how the D/H of the exchangeable reservoir may have evolved over time.
ACCEPTED MANUSCRIPT
ED
M
AN US
CR IP T
27
AC
CE
PT
Figure 6. Estimated losses to space for different values of the present loss rates. The losses are corrected for earlier EUV enhancements. The colored areas show the measured range of 3.6-25 m GEL (Jakosky et al., 2018). The darker area indicates where loss rates fall short of those required to explain the doubling of D/H since the mid-Hesperian. The upper curve is for a present loss rate of 49 m GEL in 4.2 b.y., that required to eliminate a 110 m GEL ocean assuming a 30 m GEL present inventory and earlier EUV enhancements.
Mars: Formation and fate of a frozen Hesperian ocean. Michael Carr , James Head PII: DOI: Reference:
S0019-1035(18)30166-0 https://doi.org/10.1016/j.icarus.2018.08.021 YICAR 12996
To appear in:
Icarus
Received date: Revised date: Accepted date:
16 March 2018 9 July 2018 23 August 2018
Please cite this article as: Michael Carr , James Head , Mars: Formation and fate of a frozen Hesperian ocean., Icarus (2018), doi: https://doi.org/10.1016/j.icarus.2018.08.021
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT 1 Highlights
Successive floods may have caused the accumulation of a frozen ocean over 3 billion years ago. The water was lost to space and to other cold traps such as the polar layered deposits. Past loss rates to space must have been much higher than present rates
AC
CE
PT
ED
M
AN US
CR IP T
ACCEPTED MANUSCRIPT 2
Mars: Formation and fate of a frozen Hesperian ocean.
Corresponding author: Michael Carr Institution: Address: Email:
CR IP T
US Geological Survey 345 Middlefield Rd. [email protected]
Co-author: James Head
AN US
Brown University, Providence, RI 02912, USA
M
1. Introduction
CE
PT
ED
The possibility that the northern plains of Mars could have once contained ocean-sized bodies of water has long been recognized (e.g. Baker et al., 1991; Lucchitta et al., 1986; Parker et al., 1989, 1993). Large outflow channels, widely interpreted as cut by floods, drain into the plains; the plains have low slopes (Kreslavsky and Head, 1999) and roughness (Kreslavsky and Head, 2000) comparable to terrestrial ocean basins; many features on the plains resemble sub-glacial terrestrial landforms and could have formed under a frozen ocean (Kargel et al., 1995); long, continuous breaks in slope surrounding the plains could be shorelines (Parker et al, 1993); widespread fluvial dissection of the highlands may imply an extended water source (see summary in Carr, 2006). More recently, Costard et al. (2016) and Rodriquez et al (2016) have found geomorphic features that they interpret as evidence of impact-generated tsunamis.
AC
The former presence of oceans has been suggested by two main lines of reasoning. First, high erosion rates and widespread valleys and lakes in the cratered highlands suggest that late Noachian Mars could have had a hydrologic cycle with evaporation from an ocean, precipitation on the ancient highlands to form the valley networks and drainage back into the northern lowlands basin (e.g. Baker et al., 1991; Craddock and Maxwell, 1993). Second, a precipitous drop in rates of erosion and valley network formation at the end of the Noachian has been interpreted to indicate that the climate changed from one that was warm and wet, or warm and arid (Craddock and Howard, 2003; Ramirez and Craddock, 2018), to an extremely cold and dry climate more like the present, and that a thick cryosphere developed during the transition (Clifford, 1993; Carr, 1996). Large outflow channels then formed, interpreted to be the result of massive eruption of groundwater trapped below the cryosphere (Carr, 1979; Andrews-Hanna and Phillips, 2007). The channels drained into the northern plains to form large
ACCEPTED MANUSCRIPT 3 sea or ocean-scale bodies of water that would then have frozen in the global cold and arid climate (Kreslavsky and Head, 2002a; Turbet et al., 2017). The size and fate of this later Hesperian-aged iceocean that formed contemporaneously with the outflow channels, according to this hypothesis, is the main concern of this paper. A possible earlier Noachian-aged ocean is mentioned only peripherally.
PT
ED
M
AN US
CR IP T
Almost everything about the proposed Hesperian ocean is controversial (see summary in Head et al., 2018) including the cause, the number, magnitude and timing of the contributing outflow events, whether the water would have quickly frozen so that any standing body of liquid water would have been short-lived, how compelling the evidence for tsunamis is, and where all the water subsequently went. Climatic considerations are a major source of skepticism that there could have been a long-lived liquid ocean in the Hesperian, one that survived long enough to erode topographically identifiable shorelines along its shore and to have experienced impact generated tsunamis. A long-lived, liquid, high-latitude ocean would require near-equatorial temperatures close to 273 K. Partly because of the less-luminous early Sun, greenhouse warming of a thick CO2-H2O atmosphere falls far short of that required to raise the effective surface temperature from the present 215K to in excess of 273K (e.g. Kasting, 1991; Haberle et al., 2017). The supplemental effects of other greenhouse gases, such as SO2, CH4, NH3, H2 and N2O have also been studied, but for a variety of reasons all, either independently or in combination, fail to give the required long-lived boost in temperature (summarized in Haberle et al., 2017). Temporary warming as a consequence of large impacts has also been examined (Segura et al., 2008; Palumbo and Head, 2017; Turbet et al., 2017) but such effects are more likely in the Noachian, when impact rates were much higher, than in the Hesperian. Complete discussion of all the controversies is beyond the scope of this paper. We acknowledge that large amounts of water flowed into the northern plains during large floods but are skeptical that there was a long-lived liquid ocean. Alternatively, we propose that the water from each successive flood rapidly froze to form a layer of ice (Kreslavsky and Head, 2002a, Turbet et al., 2017) and that multiple floods resulted in accumulation of a long-lived, ocean-sized body of ice, but not an ocean-sized body of liquid water. We assume that the ice slowly sublimated as water was lost to space and as changes in obliquity caused redistribution of the water. The formation and fate of this body of ice is the main concern of this paper.
AC
CE
Parker et al. (1989, 1993) and Clifford and Parker (2001) identified several features encircling the northern basin that they interpreted as shorelines of an ocean. The youngest and most easily identifiable of these proposed shorelines (the Utopia shoreline, or contact 2) is closest to an equipotential surface (Head et al., 1999). In order to explore the validity of the Hesperian ocean hypothesis, we interpret this distinctive contact as marking the edge of a frozen ocean, and we assess the implications of this hypothesis. We re-estimate the volume enclosed by this shoreline in light of recent geologic mapping and THEMIS data. We then try to reconcile this ice volume with the present near surface inventory of water. We re-examine the amounts of water that could have been lost to sinks (such as to space and to groundwater), and the amounts gained from sources other than the interpreted ice-ocean. Again, our concern here is exclusively with the youngest and best preserved of the proposed shorelines (Contact 2 or the Deuteronilus shoreline). We recognize that there could have been additional, older shorelines of Noachian age that imply much larger volumes (Clifford and Parker,
ACCEPTED MANUSCRIPT 4 2001), but these are not discussed. We are concerned here exclusively with the volume of the supposed Hesperian ice-ocean and where the water went.
AN US
2. Present inventory of near-surface water.
CR IP T
We use the contrast between the present atmospheric D/H (Villanueva et al., 2015) and the D/H in sediments from Gale Crater (Mahaffy et al., 2015) as one constraint on how the near surface inventory of water may have evolved over time. The age of Gale crater is poorly constrained but crater counts on, and superposition relations of, the sediments in the central mound suggest that they are 3.6-3.8 b.y. old and straddle the Noachian –Hesperian boundary (Thomson et al., 2011). In contrast, the outflow channels and the sediments of the northern plains that were deposited by them are upper Hesperian in age (3 to 3.5 b.y. old) (Tanaka et al. 2005). The sediments at Yellowknife bay in Gale Crater unambiguously accumulate in a lake that may have been long-lived (Grotzinger et al., 2014). Our assumption that the waters from the later outflow channels would rapidly freeze may imply, therefore, a change in surface conditions between the early and late Hesperian, and this may not survive further scrutiny.
CE
PT
ED
M
There is abundant evidence of unbound water near the martian surface, particularly at high latitudes. MOLA topography (Smith et al 1999) and MARSIS and SHARAD data (Plaut et al., 2007; Byrne, 2009) indicate that the layered deposits at the two poles combined contain 17-22 m Global Equivalent Layer (GEL) (Lasue et al., 2013; Carr and Head, 2015). Ground ice has also been detected at latitudes above 600 outside the layered terrains by gamma-ray and neutron spectrometers (Boynton et al., 2002), by ground-penetrating radar (Mouginot et al., 2010), at the Phoenix landing site (Smith et al., 2009), in images of fresh impact craters (Byrne et al., 2009) and in a latitude-dependent mantle derived from mobilization of polar ice during cycles of increased obliquity amplitude (Head et al, 2003) and thought to contain a 7-70 cm thick water global equivalent layer (GEL) today (Kreslavsky and Head 2002b). Ice layers extending from near the surface to depths of 100 m have also been observed in cliffs at latitudes as low as 550 (Dundas et al., 2018). Mouginot et al. (2010) interpret the steep decrease in the 3-5 MHz reflectivity observed by MARSIS at latitudes greater than 500 as due to the presence of ground ice, which at these latitudes is stable a few meters below the surface under present conditions (e.g. Mellon and Jakosky, 1993). Mouginot et al. (2010) estimate that the radar is effectively probing to depths of 6080 m and that at least 106 km3, or 7 m GEL, of ground ice is present outside the polar layered deposits to these depths at latitudes greater than 50 deg.
AC
Near surface ice may be present at even lower latitudes. SHARAD sounding has detected interfaces interpreted as the bases of extensive ice sheets in Utopia and Arcadia Planitiae that extend as far south as 380 (Bramson et al. 2017). Ice may also be present in the 30-50 deg latitude bands in a meters-thick, dust-ice-rich mantle, interpreted to have been deposited during recent obliquity excursions (Head et al., 2003), and in lineated valley fill Head et al., 2010), concentric crater fill (Levy et al, 2010), pedestal craters (Kadish and Head 2014), debris-covered glaciers (Plaut et al, 2009; Holt et al., 2008) and tropical mountain glaciers (Head and Weiss, 2014). Levy et al. (2014) estimate that as much as 2.6 m GEL may be present near the surface in these bands. In summary, we estimate that 20-30 m GEL of water is present in the polar layered deposits and at depths shallower than 80 m in the regions surrounding the
ACCEPTED MANUSCRIPT 5 polar layered deposits extending down to 300 latitude. We recognize that in addition to the 20-30 m GEL of near-surface water, abundant unbound water (possibly hundreds of m GEL) may exist as ice cement and secondary ice within the cryosphere at depths greater than 80 m and as groundwater below the cryosphere (Clifford, 1993). 3. Ocean volume
AN US
CR IP T
Parker et al. (1989; 1993) were the first to suggest that various linear features around the northern basin were shorelines of a former ocean. They identified two contacts, an outer contact 1 and an inner contact 2 around the northern plains that they interpreted as shorelines. Subsequent acquisition of MOLA elevation data (Smith et al., 1998) enabled the ocean hypothesis to be tested more rigorously than had previously been possible. Head et al. (1999) used MOLA altimetry data to test whether the Parker et al. shorelines represented equipotential surfaces, and found that Contact 1 (-1680 m) ranged over 11 km and was, therefore, not likely to be a shoreline. Contact 2 (-3760 m) ranged over 4.7 km, but had extensive stretches that had much less variation and could be consistent with an equipotential surface representing a shoreline.
AC
CE
PT
ED
M
Carr and Head (2003) examined in detail the geologic relations, morphology and elevations of contacts 1 and 2 in light of the MOLA altimetry data and the more precise information on location of the contacts given in Clifford and Parker (2001). They found that some contacts are clearly of volcanic origin and that contact 1, at the boundary between the southern uplands and the northern plains, has a wide spread of elevations and is unlikely to be a shoreline. In agreement with previous work, however, they concluded that large expanses of contact 2 are close to a constant elevation of around -3760 m, and could potentially be consistent with a shoreline. There was, however considerable uncertainty in the exact location of the shorelines and it was not clear how much the spread in elevation was due to the contacts not being ancient shorelines and how much was due to mis-location of the shorelines. The latter problem was particularly acute where the contact was on or close to a steep slope such as along the plains-upland boundary. Carr and Head (2002) concluded that better support for the former presence of water over large parts of the northern plains is provided by the Vastitas Borealis Formation (VBF), an Upper Hesperian thin veneer of material in the central northern lowlands overlying the Lower Hesperian volcanic ridged plains (Tanaka et al., 2005). They found that support for this interpretation came from: 1) the similarity in age between the outflow channels and the VBF, 2) the presence of the VBF at the lower ends of the outflow channels, and 3) identification of numerous features in the outcrop areas of the VBF that are suggestive of basal melting of an ice sheet (Kargel et al., 1995). Publication of the global geologic map of Mars (Tanaka et al., 2014) and the availability of global THEMIS daytime images (http://mars.asu.edu/data/thm_dir_100m/) enables a new assessment of the exact location of the proposed shorelines and, in conjunction with the MOLA data, their elevation. The availability of the geologic map is particularly useful. Identification of geologic units and the depiction of their distribution are based solely on the observed surface characteristics, having been compiled independently of any model for the northern plains or intent to prove or disprove the presence of shorelines. The THEMIS daytime images have proven particularly useful in providing a new source of data that enables better portrayal of contrasts in the textural and thermal properties of the surface,
ACCEPTED MANUSCRIPT 6 distinction between units, and sharper definition of their contacts, thereby reducing the dependence solely on topography for recognizing possible shorelines.
PT
ED
M
AN US
CR IP T
We find that one the most compelling cases for a shoreline is provided by the outer boundary of the Vastitas Borealis Formation (VBF) around the southern and western rim of the Utopia basin, as portrayed in the Tanaka et al. (2014) global geologic map (Figure 1) and in Ivanov et al. (2017). The VBF occurs widely throughout the northern plains. It is characterized by numerous closely spaced low hills, some pitted, and some arrayed in closely spaced curved ridges to form a ‘thumb-print’ texture. Areas of polygonal fractures are common, at different scales and in different locations. Locally in the interior of Utopia, graben-like linear intersecting troughs form complex networks (Heisinger and Head, 2000). A distinctive variety of surface units and textures can be distinguished, assessed stratigraphically and dated using superposed craters (Ivanov et al., 2014, 2015, 2017). Superimposed impact craters commonly have bright halos, thereby giving the unit a mottled appearance (Tanaka et al. 2005). Many of the textures have been attributed to the former presence of a frozen ocean (Kargel et al., 1995; Ivanov et al., 2014, 2015, 2017). The unit is labelled as Late Hesperian on the Tanaka et al. (2014) map but the accompanying correlation chart indicates that the unit may extend down into the Early Hesperian. Kreslavsky and Head (2002a) suggest that the unit is effluent deposited from an ocean (or multiple lakes) that formed contemporaneously with the outflow channels in the Late Hesperian. From the presence of buried ridges and ‘ghost’ craters, they estimated that the unit is approximately 100 m thick. Around the south and west margins of the Utopia basin the outer boundary of the VBF is easily recognizable in the THEMIS daytime mosaics and readily distinguishable from the surrounding units by contrasts in albedo and surface texture (Figure 2). The boundary here has little topographic expression. It closely follows the -3650 m contour for 2800 km around the south and west margins of the Utopia basin (Figure 1). It is difficult to imagine any geologic feature or process, other than a shoreline, that would so closely follow a contour over such large distances, and thus we choose to pursue this interpretation. The precise origin of such a shoreline in southern Utopia is uncertain, however. One possibility is that it marks the furthest reach of the last major flood that entered the northern basin and marks the limit of deposition of effluent from that flood. At the time of the last flood most of the water from the previous floods may have already frozen to form a solidified ice-ocean.
AC
CE
Away from southern Utopia the -3650 m contour as a shoreline is not so compelling (Carr and Head 2002) although its characteristics are not inconsistent with this interpretation. To the east of Utopia Planitia the contour crosses Amazonian volcanics that extend from Elysium down into the northern basin, so any Hesperian or older shoreline that might have been formerly present would now be buried. Similarly, the VBF abuts against younger units in northern Arcadia Planitia and north of Alba Patera. It is not clear how far south the VBF, and hence any potential shoreline, extended into Arcadia Planitia because of the presence of these younger deposits. The -3650 m contour follows the steep outer boundary of the Olympus Mons aureole deposits. This boundary is almost certainly of volcano-tectonic, not marine origin (Carr and Head, 2002), yet would have been a shoreline if present at the same time as the proposed ocean marked by the -3650 m contour. If the outer aureole deposits formed subsequent to the ocean, as is likely (Tanaka et al. 2014), then the deposits would have buried the shoreline of the southern extension of the ocean into Arcadia Planitia. To the west of Utopia Planitia, the contour follows
ACCEPTED MANUSCRIPT 7 the plains/upland boundary, which is much older than the Hesperian, but which would nevertheless have been a shoreline in the Hesperian if an ocean was present up to the -3650 m elevation.
AN US
CR IP T
In Chryse Planitia, into which most of the large outflow channels empty, the -3650 m contour outlines numerous streamlined islands and other breaks in slope such as the plains-upland boundary (Figure 3). Ivanov and Head (2002) used MOLA altimetry data to show that the largest and most prominent outflow channels (Kasei, Maja, Simud, Tiu, Ares and Mawrth) debouch into Chryse Planitia and disappear into the northern lowlands at average elevations that are all within less than ~170 m of a mean elevation of 3742 m, all within 190 m of the elevation of contact 2, over a lateral distance of over 2500 km. They proposed that the distinctive change of channel morphology could be consistent with a rapid loss of stream energy encountered at a base level such as a subaerial/submarine boundary. Contact 2 does not follow the VBF boundary specifically, which is to the north further into the basin. The -3650 m contour here is an erosional boundary rather than what appears to be a depositional boundary in Utopia Planitia. Possible explanations in the context of this interpretation are that late stage floods removed the VBF in Chryse or that the rapidly moving floods entering Chryse Planitia eroded the ocean floor and did not deposit their sediment load until well below the -3650 m contour (Ivanov and Head, 2002).
ED
M
The fate of the water released by the outflow channels and any deposited in an ocean would have depended on the climatic conditions under which it formed. Turbet et al. (2017), using 3-D Global Climate Model simulations, explored the release of water in individual outflow channel events, its fate, and its effect on the climate. They modeled the short and long term climatic impacts of a wide range of outflow channel formation events under cold Mars conditions interpreted to exist in the Late Hesperian, and found that even the most intense (largest, highest flux) of these events cannot trigger long-term greenhouse global warming. In a typical event, the outflow channel water reaches the bottom of the basin in a few days, and freezes over within just a few hundred days. It then sublimates to cold traps at the poles possibly within a few hundred thousand years.
AC
CE
PT
An ocean would clearly have to have accumulated by multiple events as indicated by the number of outflow channels entering the basin. If, as appears likely and as described above, global climate conditions were similar to present conditions and a thick cryosphere was present (required for the overpressurized aquifer origin for the outflow channels), then the body of water that formed after each event would have frozen within a geologically short period of time (103 to 104 years depending on the size of the event; Kreslavsky and Head , 2002a; Turbet et al., 2017). The ice could potentially stabilize and remain between outflow channel events if a sublimation lag was formed rapidly after each event (Kreslavky and Head, 2002; Bramson et al., 2017). Mellon and Jakosky (1995) show, for example, that under conditions expected at an obliquity of 300, ice is stable at all latitudes at depths greater than a 1020 cm. In this specific scenario, repetitive floods could build an ocean-sized body of ice, layer upon layer as each water outflow event built on the frozen, sublimation lag protected, earlier layers. Once the era of flooding ended the ice would slowly sublimate, possibly over hundreds of thousands to millions of years, with the water being both lost to space and redistributed across the martian surface (Figure 4). According to this scenario, the -3650 m shoreline never enclosed an ocean-sized body of liquid water; rather, it marked the edge of the last outflow channel flood that flowed across the northern basin, which at the time would be almost completely filled with ice from the previous floods. For the rest of
ACCEPTED MANUSCRIPT 8 this paper, we will assume this specific scenario, that in the mid-late Hesperian, there was a solidified ice-ocean in the northern plains composed of residual ice layers from the individual outflow channel events. The -3650 m contour, enclosing ~110 m GEL marks the limit of the final flooding event. We will attempt to determine where the 110 m GEL of water went. We saw above that we can account for approximately 20-30 m GEL in currently existing deposits, so that approximately 80-90 m is unaccounted for.
CR IP T
4. Outgassing
AC
CE
PT
ED
M
AN US
In order to know what fraction of the present 30 m near-surface inventory of water has been inherited from the Hesperian we need to know how much has volcanically outgassed since that time. To determine this we used a procedure somewhat similar to that used by Greeley (1987) and Greeley and Schneid (1991). The volume of extrusives was derived from the areas of volcanic units, as depicted on the available geologic maps, coupled with thicknesses derived from the burial of craters; then an assumption was made about the water content of the lavas. Our procedure was as follows. The areas of different volcanic plains units were taken from Table 6 in the brochure accompanying the global geologic map of Tanaka et al. (2014). The thickness was estimated by finding the thickness needed to bury all craters on the underlying unit within the mapping resolution, which was assumed to be 105 km2, on the assumption that if there were more craters than the designated age, then that 105 km2 would have been mapped as the older unit. The number of craters on the different aged buried surfaces was determined from equation 13 and Table III in Ivanov (2001), taking into account protection from cratering by the overlying unit. The surface underlying Amazonian units was assumed to have ND(3.8)N(D) (3.0) craters upon it, where ND(3.8) is the number of craters of diameter (D) that has accumulated on a 3.8 b.y. old surface. Similarly, a surface underlying a Hesperian unit was assumed to have ND(4.0) – N(D) (3.8) craters upon it. Rim heights as a function of diameter were taken from Garvin et al. (2002). The procedure suggests a minimum thickness of 800 m for Hesperian plains units (very similar to the 800-1000 m estimates for the Hesperian ridge plains in the northern lowlands derived by different techniques; Head et al., 2002) and 500 m for Amazonian plains units. In addition, edifice volumes from Plescia (2004) were assumed to have accumulated at a constant rate through the Amazonian and Hesperian. Following this procedure we derive extrusive volumes of 1.21 x 107 km3 for the Amazonian and 1.24 x 107 km3 for the Hesperian. These numbers are smaller than those of Greeley and Schneid (2.6 x 107 and 3.3 x 107 km3) mainly because of the smaller areas depicted as volcanic on the Tanaka et al. (2014), map as compared with earlier maps. Intrusives (probably mostly in the form of dikes; e.g., Head et al., 2006) are not included in the estimates. For estimating the effect of outgassing on D/H (see below) we assume, consistent with these figures, that volcanism has declined exponentially over the last 3.5 b.y and that the cumulative volume, V, over the last t billion years (t = 0 to 3.8) is given by V=2.56e7*(1-exp(-0.83*(3.8-t))). The D/H was assumed to be 1 x SMOW (Standard Mean Ocean Water). A significant problem in estimating the amount of water outgassed is in knowing the amount of water originally present in the magmas and the fraction of this amount that was outgassed to the atmosphere. Estimates of the water contents of the Shergottite parent liquids range from 0.0075 to 2.8% (McCubbin et al., 2012; Usui et al. 2012). Following Greeley (1987) and Greeley and Schneid (1991), we assumed that one wt. percent is outgassed, which gives 5 m GEL for the total amount of water outgassed in the
ACCEPTED MANUSCRIPT 9 Amazonian and Hesperian. A later estimate used 0.5 wt. percent water on the basis of terrestrial data (Craddock and Greeley, 2009). These assumptions, if valid, imply approximately 5 m GEL of the present 30 m inventory was added by volcanism after the end of the Noachian.. 5. Infiltration into the ground.
CR IP T
Clifford (1987, 1993) suggested that, despite the presence of a near-global cryosphere during much of Mars’ history, the planet may have maintained a slow global hydrological cycle as meltwater at the base of the polar layered deposits infiltrated into the groundwater system to create a groundwater mound and cause percolation equatorward under the cryosphere. At low latitudes, the groundwater was episodically returned to the surface as a result of impacts, seepages and eruptions of groundwater, thereby completing the cycle. The proposed circulation is driven by the infiltration of meltwater at the poles. Here we examine the plausibility of melting at the base of the polar deposits in light of recent estimates of the global heat flow as a function of time.
PT
ED
M
AN US
Present estimates of global heat flow are significantly less than when the Clifford model was formulated, and these lower heat flow values make it unlikely that basal melting could occur at the poles during the Amazonian and Hesperian. A model by Stevenson et al. (1983), for example, predicted a present heat flow of 30 mW m-2 for present day Mars and approximately 100 mW m-2 at the Amazonian-Hesperian boundary 3 b.y. ago. In contrast, from the geodynamical response of the lithosphere to the presence of the polar deposits, Phillips et al. (2008) estimate that the present heat flow at the north pole is in the 817 mW m-2 range. In addition, McGovern et al. (2002) and Ruiz et al. (2011) have inferred lithosphere thicknesses and heat flows for a number of regions of Mars from gravity/topography admittance spectra. Estimated heat flow values, while in excess of 40 mW/m2 for most Noachian features, are in the 10 to 40 mW/m2 range for Amazonian and Hesperian features except for the large Tharsis volcanoes which have larger local values (Cassanelli et al., 2015). The lower heat flow estimates have also been compared and reconciled with geochemical models (Ruiz, 2014). The upper limit for heat flow (mW m2 ) as a function of time given in Ruiz (2014) was approximated by H = 14.4 + 5.6t -1.61t2 + 0.8t3
AC
CE
where t is the time before present in billions of years. According to this formulation the heat flow is 14.4 mW/m2 at present and 38 mW/m2 at 3 Ga. For a surface temperature of 150K, a basal temperature of 273K and a thermal conductivity of 2W m-1 K-1 (Clifford, 1987), the polar deposits would have to be over 6 km thick for basal melting 3 b.y. ago, over 9 km thick 2 b.y. ago and over 12 km thick 1 b.y. ago. The present deposits are approximately 3 km thick. We conclude, therefore, that polar basal melting has been unlikely since the Hesperian ocean was present and loss of water though the poles into the groundwater system can be ignored. Basal melting may, however, have been significant during the Noachian when heat flows and possibly surface temperatures were higher. Following earlier work (Harrison and Grimm, 2004; Russell and Head, 2007), Cassanelli et al. (2015) assessed the possibility that snow and ice accumulation on Tharsis could be sufficient to cause basal melting and recharge of the groundwater system. They found, however, that even the heat flow at Tharsis would be insufficient to
ACCEPTED MANUSCRIPT 10 cause significant basal melting and recharge, except under the very localized and volumetrically insignificant volcanic edifice heatpipe/drainpipe situation.
6. Loss of equatorial ice and groundwater to the atmosphere.
CR IP T
Another possibility is that the Hesperian ocean formed under warm climatic conditions before a global cryosphere developed and that some significant fraction of the ocean evaporated, thereby causing precipitation and infiltration into the groundwater system in the surrounding regions. There is, however, little evidence to support such a scenario (Turbet et al., 2017). The outflow channels that are interpreted to have caused the ocean are largely undissected by valley networks as are many plains that clearly pre-date the outflow channels, such as Lunae Planum in the case of Kasei Vallis.
PT
ED
M
AN US
One of the more puzzling aspects of the evolution of near-surface water is the role of the loss of water from the equatorial cryosphere. Under present climatic conditions, ice present at the near-surface at low latitudes will tend to sublimate and be transferred to the atmosphere, thereby causing depletion of the near-surface ground ice (Fanale, 1986; Clifford and Hillel, 1983). The depth of depletion will increase in time at a rate dependent on the properties of the near-surface materials and conditions at the surface, with a particular sensitivity to conditions at different obliquities. This could result in substantial transfer of equatorial ground ice to the polar regions over geologic time. Grimm and Painter (2009), and Grimm et al. (2017) estimate, for example, that approximately 60 m GEL would have been removed from the equatorial regions after the transition to modern cold, dry surface conditions in the early Hesperian, most of the losses having taken place in the first billion years. They assume an abrupt transition at 3 B.Y. ago from an earlier climatic regime that allowed retention of equatorial ice to the “modern” regime under which such ice is unstable. The losses are consistent with the scarcity of nearsurface ice at latitudes less than 50-60 deg. as indicated by neutron spectrometer (Feldman et al., 2004) and MARSIS (Mouginot et al, 2010) data. As we saw above, recycling of water through polar basal melting is unlikely, so the ice removed from the equatorial regions would remain near the surface at high latitudes or be lost to space. The water lost would have had a D/H of the near-surface reservoir at the time of transition, which is assumed to be that of that of the Hesperian aged clays at Gale crater (3 x SMOW) (Mahaffy et al. 2015).
AC
CE
If this reasoning is even approximately valid, it would imply that a significant fraction of the present near-surface inventory of water is derived from equatorial ground ice, not directly from a Hesperian ocean and that we would have to account for the fate not only of the 110 m GEL estimated to have been in the ice-ocean, but also the additional approximately 65 m GEL derived from the equatorial cryosphere. However, initiation of loss of groundwater and ground ice from the equatorial regions probably occurred much earlier than the 3 Ga assumed by Grimm et al. (2017). The transition more likely occurred at the end of the Noachian, 3.8 b.y. go, as indicated by the rapid drop off of the rate of formation of valley networks at that time. Indeed, loss of equatorial groundwater may have been a contributing factor in the subsequent filling of the northern basin both by eruption of groundwater to form the outflow channels and by direct transfer from the equatorial cryosphere to the polar regions through the atmosphere. As a result of these uncertainties we do not include additions from the equatorial cryosphere in our assessment of the fate of the water that formerly filled the northern basin.
ACCEPTED MANUSCRIPT 11 We assume that the equatorial losses, even if they were substantial, occurred earlier than the final phase of filling the northern basin indicated by the Deuteronilus shoreline). 7. Exchange between near-surface ice and the atmosphere and other reservoirs.
AC
CE
PT
ED
M
AN US
CR IP T
The evolution of the D/H of the near-surface water reservoir provides clues concerning the fate of water that formed the ice-ocean. Water in the present atmosphere has a value of 6-7 x SMOW (Owen et al., 1998; Aoki et al. ,2015; Villanueva et al., 2015). The value for the mid-Hesperian is approximately 3 x SMOW (Mahaffy et al., 2015). The main cause of the long-term doubling of the D/H of near-surface water since the mid-Hesperian is losses to space from the upper atmosphere (e.g. Yung et al. 1988). To understand the implications of the D/H measurements, we need to know the size of the water reservoir that is being affected by such losses. We saw above that the bulk of the near-surface inventory of water (17-22 m GEL) is in the polar deposits. Observational evidence and modeling suggest that the polar layered deposits are geologically young and dissipate and re-accumulate on geologically short time scales. Crater counts indicate that the north polar layered deposits (NPLD) are only ~105 years old (Herkenhoff and Plaut, 2002). The south polar layered deposits (SPLD) are much older, ranging from 107 to 108 years (Herkenhoff and Plaut, 2002; Koutnik et al., 2002), but are still late Amazonian in age. Levrard et al. (2007) modelled the exchange of water between the poles and low latitudes using a 3dimensional global climate model. Their results indicate that the NPLD completely dissipated during a period of high (> 30 degrees) obliquities 5-10 Ma ago and that they have been re-accumulating during the last 4 Ma as mean obliquity decreased to the present value of 25 degrees. The NPLD are now in an accumulation phase, hence their young age. Superimposed on this long term trend are smaller oscillations. Most recently, geologically, polar water is thought to have been transferred from the poles to lower latitudes where it formed latitude-dependent, ice-rich mantles (Head et al., 2003); the most recent north polar deposits are likely to be derived from the sublimation of the southern part of the latitude dependent mantle. On longer time scales, but still in the late Amazonian, when mean obliquity exceeded 30 degrees, more widespread equatorward transfer of polar ice is interpreted to have resulted in regional ice deposits in the mid-latitudes, including glaciers, lobate debris aprons (LDA), lineated valley fill (LVF) and concentric crater fill (CCF) (Head et al., 2010; Levy et al., 2014; Kadish and Head, 2014; Madeleine et al., 2009; Fastook and Head, 2014). Tropical mountain glaciers are interpreted to have accumulated when the mean obliquity was ~45 degrees (Head and Marchant, 2003; Forget et al., 2006; Fastook et al., 2008). The south polar deposits are more stable than those in the north but still appear to have exchanged with the atmosphere on geologically short time scales (100 Ma). There is little reason to think that the spin-axis/orbital factors that govern the transfer of ice in the present epoch are different from those operating at other times during the last 3.5 Ga, although their amplitudes will differ (Laskar et al., 2004). The polar layered deposits are likely to have been dissipating and re-accumulating throughout this period, with their D/H increasing as a consequence of losses from the upper atmosphere. It is less clear how well the 10 m GEL of ice deposits peripheral to the pole have exchanged with the atmosphere, but the presence of mid-latitude ice sheets and tropical mountain glaciers during this period means that at least some of the ice in the upper part of the regolith is being mobilized as cold traps migrate. Laskar et al. (2004) estimate that there is a 90% probability that obliquity reached 47 degrees in the last 20 Ma, which would have led to more widespread loss of polar
ACCEPTED MANUSCRIPT 12 ice than occurred during the recent episode when obliquities were mostly in the 30-40 degree range. In summary, it is likely that on a time scale of ~100 Ma, all of the 17-22 m GEL polar ice undergoes exchange with the atmosphere as does much of the 10 m GEL near the surface in the circum-polar regions.
AN US
CR IP T
Based in part on D/H measurements, Kurokawa et al. (2014; 2015) proposed a three-reservoir model for the distribution of water (the atmosphere, a near-surface reservoir exchangeable with the atmosphere and a deeper ground-ice reservoir). The D/H in the atmosphere and near-surface reservoir co-evolve, differing only as a result of the fractionation factor between ice and vapor. The D/H of the deeper ground ice retained the value it had at the time of transition from a hypothesized warm and wet/arid Craddock and Howard, 2002; Ramirez and Craddock, 2018), vertically integrated hydrologic regime around 3.8-4.0 b.y. ago, to the present horizontally stratified regime with a global cryosphere. Kurokawa et al. (2014; 2015) suggest that there could have been slow exchange between the deep ground ice and the near-surface reservoir as a result of infiltration, hydrothermal activity, impacts and diffusion. The exchangeable reservoir is held constant in the model, with losses to space from the exchangeable reservoir being offset by net additions from the underlying reservoir. From meteorite data (Usui et al. 2012), they assume that the deep ground ice has a D/H of 1-2 x SMOW. With these assumptions they estimate that a few tens of meters GEL of water have been lost to space for D/H fractionation factors of 0.016 to 0.11, and a few tens to hundreds of meters GEL for a fractionation factor of 0.33.
AC
CE
PT
ED
M
We assume here a similar model, in which a near-surface reservoir that exchanges with the atmosphere overlies a larger ground-ice reservoir that interacts episodically with the overlying exchangeable reservoir. As water is lost from the exchangeable reservoir, its D/H increases and the losses are replaced by incorporating ice from the underlying reservoir, which retains mid-Hesperian D/H of 3 x SMOW (Mahaffy et al, 2015) . The size of the exchangeable reservoir depends on the time scale of interest. In the present epoch, on a time scale of 103 years, the deeper layers of the NPLD are sealed from the atmosphere and so do not interact with it, but on a time scale of 105 years all the NPLD interact with the atmosphere. On time scales of 108 years, because of excursions to higher obliquities, a larger volume exchanges with the atmosphere. The SPLD are erased and the areas peripheral to the poles exchange with the atmosphere (Levrard, 2007). We are interested here in the long term evolution (3.5 b.y.) and the volume that is exchanging and equilibrating with the atmosphere on time scales of 108 years. We will assume that all the NPLD, all the SPLD, and the ground-ice peripheral to the poles to a depth of 80 m, a total of 20-30m GEL, all interact with the atmosphere on times scales of 108 years, and that this volume has been approximately constant for the last 3.5 b.y. 8. Losses to space.
If the atmosphere has been episodically exchanging with a reservoir of near-surface ground ice, as just discussed, then the high D/H ratio of the atmosphere (and by implication the exchangeable ice reservoir) indicates a substantial loss of hydrogen to space. At present day loss rates the equivalent of only 3.6-25 m GEL of water would have been lost over the last 4.2 b.y. (Jakosky et al., in press). Such a low loss rate is incompatible with the evolution of D/H and the size of exchangeable reservoir as just
ACCEPTED MANUSCRIPT 13 described. If there had been no loss or gain of water between the near-surface exchangeable reservoir and the deeper surface, then the Hesperian and present inventories would be related by the expression IH = IP (Rp/RH)(1/1-f)
CR IP T
where IH and IP are the Hesperian and present near-surface inventories, RH and RP are the Hesperian and present D/H ratios, and f is the fractionation factor (Donahue, 1995). Even in the extremely unlikely case of no deuterium lost to space (f=0), a present inventory of 20-30 m and a doubling of the D/H (see above), would imply that at least 20-30 m has been lost.
M
AN US
As noted by almost all who have addressed the issue of losses to space from the upper atmosphere , the loss rates depend on the long term history of the output of the Sun, particularly in the EUV. Comparisons with nearby stars indicate that in the first few hundred million years the Sun’s EUV output declined from 100’s to 10 times the present value. Gudel (2007) and Gudel and Kasting (2011) estimate that by 3.5 b.y. ago the output had declined to 6 times the present value. Their data on the decline can be approximated by the relationship log E = 0.0647e0.726t where E is the enhancement over present rate and t is the time before the present in billions of years. There are uncertainties concerning the dependence of escape rates for oxygen and hydrogen on the intensity of EUV. We assume here a linear dependence. There is also some uncertainty as to whether the solar ages are exactly equivalent to the martian crater ages. The solar ages assume the Sun’s early history is typical of that of nearby stars and derivation of crater ages depend on crater scaling laws and knowledge on the mix of objects in the early Solar System. Such discrepancies could be significant in view of the rapid fall off in the EUV between 3 and 4 billion years ago.
CE
PT
ED
Higher obliquities may also have caused higher hydrogen loss rates in the past. Mellon and Jakosky (1995) suggested that higher obliquities would result in higher column abundances of water in the atmosphere as more water is transferred from pole to pole with the seasons. Their estimated increases are substantial, with an over two orders of magnitude increase from the present 250 to the average obliquity of 420 over the last 4 b.y. Such increases in the water content of the atmosphere could result in significantly enhanced losses from the upper atmosphere. Mischna and Richardson (2005) suggest, however, that this effect may have been overestimated.
AC
Early estimates of the losses of oxygen to space vary widely from the equivalent of 5-15 m GEL of water (Lammer et al. 2003) to 50-80 m GEL (Kass and Yung, 1995; Luhmann et al., 1992). More recently, Jakosky et al. (2017) estimated oxygen losses from MAVEN measurements of 38Ar/ 36Ar in the upper atmosphere. They conclude that as much as a half a bar of CO2 could have been removed by sputtering through time. They note that if the O lost came from H2O then water losses could have been “substantial”. However, even if most of the O lost was from water, it remains unclear when the water was lost, whether before or after formation of the Deuteronilus shoreline. We are interested here in losses in the last ~3.5 billion years, that is since formation of the Hesperian ice-ocean and much of the “substantial” loss could have taken place before that time. 9. Evolution of D/H.
ACCEPTED MANUSCRIPT 14
CR IP T
For the present and Hesperian inventories of 30 m and 110 m GEL, and D/H values of 6 and 3, equation 1 implies a fractionation factor of 0.46 which is a higher value than most published values (e.g. Krasnapolsky, 2000: Yung et al, 1988). But as we saw above, the near-surface reservoir has not been isolated from the rest of the planet and volcanism has added to the surface inventory. Moreover , the loss of 80 m GEL over the last 3.5 b.y. implies a substantially larger present-day loss rate of hydrogen than the early MAVEN estimates (Jakosky, in press), even taking into account the higher, earlier EUV enhancements.
M
AN US
In order to determine how the mid-Hesperian ice inventory of 110 m GEL with a D/H of 3 x SMOW might have evolved to the present near-surface exchangeable inventory of 20- 30 m GEL with a D/H of 5-7 x SMOW, a spread sheet was constructed which started with the present situation and stepped back in time in 100 m.y. increments. At each step the losses to space were calculated starting with different nominal values for present day loss rates and scaling with time to account for the past higher EUV as described above under Losses to Space. Additions as a result of outgassing were made as also described above, using 1 x SMOW for D/H. The exchangeable volume, nominally 30 m GEL was kept constant by adding from a deeper non-exchangeable reservoir with a D/H of 3 x SMOW in order to replace losses from above. The value of 3 x SMOW is based on the assumption that the nonexchangeable reservoir has been protected from interaction with the atmosphere since the ice ocean was present. With these constraints the fractionation factor that results in evolution of D/H of the exchangeable reservoir from 3 x SMOW at 3.5 b.y. ago to the present value of 5-7 was determined by trial and error. Typical results are shown in Figure 5.
CE
PT
ED
Assuming a present inventory of 30 m GEL of which 4 m is derived from outgassing, then 84 m GEL must be lost to space to eliminate the 110 m GEL estimated to have been in the Hesperian ocean. Present loss rates of 4-25 m GEL in 4.2 b.y. (Jakosky, 2016) fall well short of the required rates even correcting for the earlier higher EUV fluxes . A present day loss of 25 m GEL in 4.2 b.y. implies a loss of 42 m GEL in 3.5 b.y., or half the required loss, even taking into account the higher earlier EUV fluxes. In addition, doubling of the D/H since the mid Hesperian requires present day loss rate of at least 21 m GEL in 4.2 b.y. , that required in the unlikely event of no losses of deuterium since the mid-Hesperian (figure 6). In order to lose the 84 m GEL to space estimated to be required to eliminate the 110 m GEL ocean, we estimate that a present day loss rate of 49 m GEL in 4.2 b.y. is required, almost double the measured rate.
AC
One possibility for the shortfall is that the losses to space have been underestimated. This could occur because the measured rates are not typical of the present epoch, because the effects of the early EUV enhancements were underestimated or because possible higher loss rates during periods of high obliquity were not taken into account. Another possibility is that the present near-surface inventory has been underestimated. Mouginot et al. (2010) acknowledge that their estimate from MARSIS of 7 m GEL outside the polar caps at depths less than 60-80 m is a lower limit. We argued above that significant amounts of water sublimated from the ice-ocean could not have re-entered the groundwater system because of the presence of a thick cryosphere. If true, the missing volume, if not lost to space, must be near the surface. It must also be outside the -3650 m contour that defines the 110 m volume of the basin and at latitudes greater than 300 because of stability constraints. Since the basin occupies most
ACCEPTED MANUSCRIPT 15
CR IP T
of the northern hemisphere at latitudes greater than 300, the missing volume, if still present, is most likely at high southern latitudes. Consistent with this conclusion, seven of the eight cliffs in which layers of ice have been observed are in the 55-600 S. latitude band (Dundas et al., 2018). The southern latitudes in excess of 300 constitute only one quarter of the planet’s surface area so to accommodate the missing 30-55 m the southern high latitudes would have to typically be underlain by 120-220 m of ice. While this seems an improbably large amount, the ice layers observed by Dundas et al. (2018) are tens of meters to over 100 m thick so that the high southern latitudes could contain a significant fraction of the missing volume. 10. Conclusions.
AC
CE
PT
ED
M
AN US
1. In the mid to late Hesperian, floodwaters repeatedly flowed into the northern basin under climatic conditions that resemble those of the present day. We assume that each flood froze in a geologically short period of time to form an ice layer that remained there until the next flood. Successive ice layers accumulated to form an ocean-sized body of ice that filled the basin up to the -3650 m contour thereby enclosing 110 m GEL of water. 2. Subsequent to the filling of the basin the ice slowly sublimated into the atmosphere to be lost to space or to accumulate in various near-surface cold traps such as the polar layered deposits. 3. Only minor amounts of water were lost from the surface to the global groundwater system because of the thick cryosphere and low heat flow values. The minor amounts lost were in places where anomalously high heat flow values prevailed as in active volcanic edifice regions. 4. 20-30 m GEL of water are estimated to be near the surface today and exchanging with the atmosphere on geologic time scales. This includes the polar layered deposits and deposits elsewhere at depths less than approximately 80 m. A non-exchangeable reservoir of unknown capacity underlies the exchangeable reservoir. 5. Approximately 5 m of water has been outgassed to the surface since the mid Hesperian. 6. Present day loss rates to space fall far short of those needed to eliminate the volume of the mid Hesperian ice ocean and those needed to cause a doubling of the D/H of the exchangeable reservoir since the mid Hesperian. Earlier loss rates must have been higher. Assuming a linear increase in loss rates because of the higher EUV output of the Sun, a 30 m present inventory, and the upper limit on present loss rates from MAVEN, 42 m GEL of water remain to be accounted for. Possibilities include greater dependence of losses of EUV than assumed and enhanced losses during periods of high obliquity. In addition, large volumes of ice may be present near the surface at high southern latitudes as indicated by recent discoveries of ice layers in cliffs.
Acknowledgements. The paper was improved substantially following comments from attendees at the 4th Early Mars Conference, Flagstaff, Oct 1-6, 2017 and by thoughtful reviews by R. Irwin and an anonymous reviewer. JWH gratefully acknowledges support for participation in the Mars Express High-Resolution Stereo Camera (HRSC) team (JPL 1237163).
REFERENCES
ACCEPTED MANUSCRIPT 16
AC
CE
PT
ED
M
AN US
CR IP T
Andrews-Hanna, J.C., Phillips, R.J., 2007. Hydrological modeling of outflow channels and chaos regions on Mars. J. Geophys. Res. Planets, 112, E08001. https://doi.org/ 10.1029/2006JE002881. Aoki, S., Nakagawa, H., Sagawa, H., Gierann, M., Sindoni. G., Aronica, A. and Kasaba, A., 2015. Seasonal variation of the HDO/H2O ration in the atmosphere of Mars at the middle of northern spring and beginning of northern summer. Icarus, 260, 7-22. Baker, V. R., Strom, R. G., Gulick, V. C., Kargel, J. S., Komatsu, G. and Kale, V. S., 1991. Ancient oceans, ice sheets and the hydrologic cycle on Mars. Nature, 352, 589-59. Boynton, W. V. and 24 colleagues, 2002. Distribution of hydrogen in the near-surface of Mars: Evidence for subsurface ice deposits. Science, 296, 81-85. Bramson, A. M., Byrne, S. and Bapst, J., 2017. Preservation of mid-latitude ice sheets on Mars. J. Geophys. Res., 122, 2250-2260. DOI: 10.1002/2017JE005357. Byrne, S., and 18 colleagues, 2009. Distribution of mid-latitude ground ice on Mars from impact craters. Science, 325, 1674-1676. DOI: 10.1126/science.1175307 Byrne, S., 2009. The polar deposits of Mars. Ann. Rev. Earth Planet. Sci., 37, 535-560, doi: 10.1146/annurev.earth.031208.100101. Carr, M. H., 1979, Formation of martian flood features by release of water from confined aquifers. Jour. Geophys. Res., 84, p. 2995-3007. Carr, M. H., 1996. Water on Mars. Oxford Press, New York Carr, M. H., 2006. The Surface of Mars. Cambridge University Press, Cambridge. Carr, M. H. and Head, J. W., 2002. Oceans on Mars: An assessment of the observational evidence and possible fate. JGR, 108, E5, doi10.1029/2002JE001963. Carr, M. H., and Head J. W., 2015. Martian surface/near-surface water inventory: Sources, sinks, and changes with time. Geophys. Res. Lett., 42, 726-732. Cassanellii, J. P., and Head, J. W., 2016. Lava heating and loading of ice sheets on early Mars: Predictions for meltwater generation, groundwater recharge, and resulting landforms. Icarus, 271, 237-264, doi: 10.1016/j.icarus.2016.02.004. Cassanellii, J. P., and Head, J. W., 2018a. Formation of outflow channels on Mars: Testing the origin of Reull Vallis in Hesperia Planum by large-scale lava-ice interactions and top-down melting. Icarus, 305, 56-79, doi: 10.1016/j.icarus.2018.01.001. Cassanellii, J. P., and Head, J. W., 2018b. Large-scale lava-ice interactions on Mars: Investigating its role during Late Amazonian Central Elysium Planitia volcanism and the formation of Athabasca Valles. Planetary and Space Science, 158, 96-109.Cassanelli, J. P., Head, J. W., and Fastook, J. L., 2015. Sources of water for the outflow channels on Mars: Implications of the Late Noachian "icy highlands" model for melting and groundwater recharge on the Tharsis rise. Planet. Space Sci., 108, 54-65, doi: 10.1016/j.pss.2015.01.002. Citron, R. I., Manga, M., and Hemenway, J., 2018. Timing of oceans on Mars from shoreline deformation. Nature, 55, 643-646. Clifford, S. M., 1987. Polar basal melting on Mars. J. Geophys. Res., 92, 9135-9152. Clifford, S. M. 1993. A model for the hydrologic and climatic behavior of water on Mars, J. Geophys. Res., 98(E6), 10,973–11,016, doi:10.1029/93JE0022. Clifford, S. M. and Hillel, D., 1983. The stability of ground ice in the equatorial region of Mars. J. Geophys. Res. 88, 2456-2474, doi:10.1029/LB088iB03p02456. Clifford, S. M. and Parker, T. J., 2001. The evolution of the martian hydrosphere: Implications for the fate of a primordial ocean and the current state of the northern plains. Icarus, 154, 40-79. Costard, F., Séjourné, A., Kelfoun, K., Clifford, S., Lavigne, F., Di Pietro, I., and Bouley, S., 2017. Modeling tsunami propagation and the emplacement of thumbprint terrain in an early Mars ocean. J. Geophys. Res., 122, 633-649.
ACCEPTED MANUSCRIPT 17
AC
CE
PT
ED
M
AN US
CR IP T
Craddock, R. A. and Maxwell. A. D., 2002. The case for rainfall on a warm, wet early Mars. J. Geophys. Res., 98, 3453-3468. Craddock, R. A. and Greeley, R., 2009. Minimum estimates of the amount and timing of gases released into the martian atmosphere from volcanic eruptions. Icarus, 204, 512-526. Dundas, C. M. and 12 colleagues, 2018. Exposed surface ice sheets in the Martian mid-latitudes. Science, 359, 199-201. DOI: 10.1126/science.aao1619. Fanale, F. P., Salvail, J. R., Zent, A. P., and Postawko, S. E., 1986. Global distribution and migration of subsurface ice on Mars. Icarus, 67, 1-18. Fastook, J. L. and Head, J. W., 2014. Amazonian mid- to high-latitude glaciation on Mars: Supply-limited ice sources, ice accumulation patterns, and concentric crater fill glacial flow and ice sequestration. Planet. Space Sci., 91, 60-76, doi: 10.1016/j.pss.2013.12.002. Fastook, J. L., Head, J. W. and Forget, F., 2008. Tropical mountain glaciers on Mars: Altitude-dependence of ice accumulation, accumulation conditions, formation times, glacier dynamics, and implications for planetary spin-axis/orbital history. Icarus, 198, 305-317, doi:10.1016/j.icarus.2008.08.008. Feldman, W. C. and 15 colleagues, 2004. The global distribution of near surface hydrogen on Mars. J. Geophys. Res.109 (E9) doi:10.1029/2003LE02160. Garvin, J. B., Sakimoto, S.E. H., Frawley, J. J. and Schnetzler, S., 2002. Global geometric properties of martian impact craters. LPSC XXXIII, Abstract 1255. Greeley, R., 1987. Release of juvenile water on Mars: Estimated amounts and timing associated with volcanism. Science, 236, 1653-1654. Greelely, R., and Schneid, B. D., 1991. Magma generation on Mars: Amounts, rates and comparisons with Earth, Moon and Venus. Science, 254, 996-998. Grimm, R. E., and Painter, S. L., 2009. On the secular evolution of groundwater on Mars. Geophys. Res. Lett., 36, L24803, doi:10.1029/2009GL041018. Grimm, R. E., 2017. On the secular retention of groundwater and ice On Mars. J. Geophys. Res., 122, 94-109. doi: 10.1002/2016JE005132. Grotzinger, J. P., and 71 others, 2014. A habitable fluvio-lacustrine environment at Yallowknife Bay, Gale Crater, Mars. Science, 343, 1242777. Harrison, K.P., Grimm, R.E., 2004. Tharsis recharge: a source of groundwater for Martian outflow channels. Geophys. Res. Lett. 31, L14703. doi:10.1029/2004GL020502. Herkenhoff, K. E. and Plaut, J.J., 2002. Surface ages and the resurface rates of the polar deposits on Mars. Icarus, 144, 243-253. Haberle, R. M., Catling, D. C., Carr, M. H. and Zahnle, K.J. 2017. The early Mars climate system, in Haberle, R. M., Clancy, R. T, Forge, F., Smith, M. D. and Zurek, R. W. (Eds.), The atmosphere and climate of Mars, Cambridge Press, 526-568. Head, J. W., Hiesinger, H., Ivanov, M. A. , Kreslavsky, M. A., Pratt, S., and Thomson, B. J., 1999. Possible ancient oceans on Mars: Evidence from Mars Orbiter Laser Altimeter data. Science, 286, 21342137. Head, J. W., Kreslavsky, M. A. & Pratt, S., 2002. Northern lowlands of Mars: evidence for widespread volcanic flooding and tectonic deformation in the Hesperian period. J. Geophys. Res. 107, 5003. doi:10.1029/2000JE001445. Head, J. W. and Marchant, 2003. Cold-based mountain glaciers on Mars: Western Arsia Mons. Geology,31 (7), 641-644. Head, J. W. and Weiss, D. K. (2014) Preservation of ancient ice at Pavonis and Arsia Mons: Tropical mountain glacier deposits on Mars. Planet. Space Sci., 103, 331-338, doi: 10.1016/j.pss.2014.09.004. Head, J. W., Mustard, J. F., Kreslavsky, M.A., Milliken, R. E., and D. R. Marchant, 2003. Recent ice ages on Mars. Nature, 426, 797-802.
ACCEPTED MANUSCRIPT 18
AC
CE
PT
ED
M
AN US
CR IP T
Head, J. W., Marchant, D. R., Dickson, J. J., Kress, A. M. and Baker, D. M. 2010. Northern mid-latitude glaciation in the Late Amazonian period of Mars: Criteria for the recognition of debris-covered glacier and valley glacier land system deposits, Earth Planet. Sci. Lett., 294, 306-320, doi: 10.1016/j.epsl.2009.06.041. Head, J. W., Forget, F., Turbet, M., Cassanelli, J. and Palumbo, A., 2018. Two oceans on Mars? History, problems and prospects. LPSC 49 Abstract #2194. Herkenhoff, K. E. and Plaut, J. J.,2000. Surface ages and resurfacing rates of the polar layered deposits on Mars. Icarus 144, 243-253, doi:10.1006/icar.199.6287 Heisinger, H., and Head, J. W., 2000. Characteristics and origin of polygonal terrain in southern Utopia Planitia,Mars: Results from Mars Orbiter Laser Altimeter and Mars Orbiter Camera data. J. Geophys. Res., 105 (E5), 11,999-12,022. Ivanov, A. B.., 2001. Mars/Moon cratering rate ratio estimates, in Kallenbach, R., Geiss, J., and Hartmann (eds.), Chronology and Evolution of Mars , Kluwer, Dordrecht, 97-104. Ivanov, M. A., Heisinger, H., Erkeling, H., and Reiss, R., 2015. Evidence for large reservoirs of water/mud in Utopia and Acidalia Planitiae on Mars. Icarus 248, 383-391. Ivanov, M. A., Heisinger, H., Erkeling, H., and Reiss, R., 2014. Mud volcanism and morphology of impact craters in Utopia Planitia on Mars: Evidence for the ancient ocean. Icarus, 228, 121-140. Ivanov, M. A., Erkeling, G., Hiesinger, H., Bernhardt, H., Reiss, D.,2017. Topography of the Deuteronilus contact on Mars: Evidence for an ancient water/mud ocean and long-wavelength topography readjustments. Planetary and Space Science 144, 49-70. Kadish, S. H. and Head, J. W., 2014. The ages of pedestal craters on Mars: Evidence for a late-Amazonian extended period of episodic emplacement of decameters-thick mid-latitude ice deposits. Planet. Space Sci., 91, 91-100, doi: 10.1016/j.pss.2013.12.003. Jakosky, B. M., 2016. MAVEN observations of Mars atmospheric loss and implications for long term evolution. Fall AGU meeting, San Francisco, December, 2016. Jakosky, B. M., 2017. MAVEN observations of the Mars upper atmosphere, ionosphere, and solar wind interactions. J. Geophys. Res., Space Physics, 122, 9552-9553, DOI: 10.1002/2017JA024324 Jakosky, B. M., Slipski, M., Benna, M., Mahaffy, P., Yelle, R., Stone, S., and Alsaeed, M., 2017. Mars’ atmospheric history derived from upper-atmosphere measurements of 38Ar/ 36Ar, Science355, 1408-1410. Jakosky, B. M. and 120 colleagues, (in press). Loss of the Martian atmosphere to space: Present-day loss rates determined from MAVEN observations and integrated loss through time. Icarus, www.sciencedirect.com/science/article/pii/S0019103517306917?via%3Dihub. Kargel, J. S., Baker, V. R., Beget, J. E., Lockwood, J. F., Pewe, T. L., Shaw, J. S. and Strom, R. G., 1995. Evidence of ancient continental glaciation in the martian northern plains. J. Geophys. Res., 100, 5351-5368. Kass, D. M., and Yung, Y. L.,1995. Loss of atmosphere from Mars due to solar wind induced sputtering. Science, 268, 697-699. Kasting, J. F., 1991. CO2 condensation and the climate of early Mars. Icarus, 94, 1-13. Koutnik, M., Byrne, S. and Murray, B., 2002. South polar layered deposits of Mars. J. Geophys. Res, 107, E11, 5100, doi:10.1029/2001JE001805. Krasnopolsky, V. (2000), NOTE: On the deuterium abundance on Mars and some related problems. Icarus, 148, 597-602. Kreslavsky, M. A., and Head. J. W., 2000. Kilometer-scale roughness of Mars: Results from MOLA data analysis. J. Geophys. Res., 105 (E11), 26,695-26,711. Kreslavsky, M.A., and Head, J. W., 2002a. Fate of outflow channel effluents in the northern lowlands of Mars: The Vastitas Borealis Formation as a sublimation residue from frozen, ponded bodies of water. J. Geophys. Res., 107, E12, doi:10.1029/2001JE001831.
ACCEPTED MANUSCRIPT 19
AC
CE
PT
ED
M
AN US
CR IP T
Kreslavsky, M.A., and Head, J. W., 2002b. Mars: Nature and evolution of young latitude-dependent water-ice-rich mantle, Geophys. Res. Lett., 29 (15), 1719, doi:10.1029/2002GL015392. Kurokawa. H., Sato, M., Ushioda, M., Matsuyama. T. , Morikawa, R., and Dohm J., 2014. Evolution of water reservoirs on Mars: Constraints from hydrogen isotopes in martian meteorites. Earth and Planet Sci. Lett., 394, 179-0185. Kurokawa, H., Usui, T., and Sato, M, 2016. Interactive evolution of multiple water-ice reservoirs on Mars: insights from hydrogen isotope compositions. Geochem. J., 50, 67–79. Laskar, J., Correia, A. C. M.,Gastineau, M., Joutel, F. , Levrard, B. and Robutel ,P.,2004. Long term evolution and chaotic diffusion of the insolation quantities of Mars. Icarus, 170, 343–364. Lammer, H., Lichtenegger, H. Kolb, C., Ribas, J., GuinanE., Anart, R., and Bauer, S.,2003. Loss of water from Mars: Implications or the oxidation of the soil. Icarus, 165, 9-25. Lasue, J., Mangold, N., Hauber, E., Clifford, S., Feldman, W., Gasnault. O., Grima. C., Sylvestre, M., and Mousis, O. , 2013. Quantitative Assessments of the Martian Hydrosphere. Space Sci. Rev. 174, 155-212. Levrard, B., F. Forget, F. Montmessin, and J. Laskar, 2004. Recent ice-rich deposits formed at highlatitudes on Mars by sublimation of unstable equatorial ice during low obliquity. Nature, 431, 1072–1075. Levrard, B., Forget, F., Montmessin, F and Laskar J. 2007. Recent formation and evolution of the martian polar layered deposits as inferred from a global climate model. J. Geophys. Res. , 112, DOI: 10.1029/2006JE002772. Levy, J., Head, J. W., and Marchant, D. R. 2014. Concentric crater fill in the northern mid-latitudes of Mars: Formation processes and relationships to similar landforms of glacial origin. Icarus, 209, 390-404, doi:10.1016/j.icarus.2010.03.036. Levy, J., Fassett, C. I. , Head, J. W., Schwartz, C. and Watters, J. L., 2014. Sequestered glacial ice contribution to the global martian water budget: Geometric constraints on the volume of remnant, midlatitude debris-covered glaciers. J. Geophys. Res., DOI: 10.1002/2014JE004685. Lucchitta, B. K., Ferguson, H. M. and Summers, C. 1986. Sedimentary deposits in the northern lowland plains, Mars. Proc. 17th Lunar. Planet. Sci. Conf, J. Geophys. Res., 91, E166-E174. Luhmann, J. G., Johnson, R. E. and Zhang, M. G., 1992. Evolutionary impact of sputtering of the martian atmosphere by O+ pick up ions. Geophys. Res. Lett., 19, 2151-2154. Mahaffy, P. R., and 27 colleagues, 2015. Mars atmosphere. The imprint of atmospheric evolution in the D/H of Hesperian clay minerals on Mars. Science, 347, 412-414, doi: 10.1126/science.1260291. Madeleine, J.B. Forget, F., Head, J. W., Levrard, B., Montmessin, F., and Millour, E. 2009. Amazonian northern mid-latitude glaciation on Mars: a proposed climate scenario. Icarus, 203 (2009), pp. 390-405, 10.1016/j.icarus.2009.04.037. McCubbin, F. M., Hauri, E. H., Elardo, S. M., Kaaded, K. V., Wang, J. and Shearer, C. K., 2012. Hydrous melting of the martian mantle produced both depleted and enriched shergottites. Geology, 40, 683-686. doi:10.1130/G33242.1. McGovern, P. J., Solomon, S. C., Smith, D. E., Zuber, M. T., Simons, M., Wieczorek, M. A., et al, 2002. Localized gravity/topography admittance and correlation spectra on Mars: Implications for regional and global evolution. J. Geophys. Res., 107, E12, doi:10.1029/2002JE001854. Mellon, M., and Jakosky, B. M., 1995. The distribution and behavior of martian ground ice during past and present epochs. J. Geophys. Res., 111, 11781-11799. Mouginot, J., A. Pommerol, W. Kofman, P. Beck, B. Schmitt, A. Herique, C. Grima, A. Safaeinili and J. Plaut, 2010. The 3-5 MHz global reflectivity map of Mars by MARSIS/Mars Express: implications for the current inventory of subsurface H2O. Icarus 210, 612-625. Doi: 10.1016/j.icarus 2010.07.003.
ACCEPTED MANUSCRIPT 20
AC
CE
PT
ED
M
AN US
CR IP T
Owen, T., Maillard, J. P., de Berg, C and Lutz, B. L., 1988. Deuterium on Mars: The abundance of HDO and the value of D/H. Science, 240, 1767-1770. Palumbo, A. M., and Head, J. W., 2017. Impact cratering as a cause of climate change, surface alteration, and resurfacing during the early history of Mars. Meteoritics & Planetary Science, in press, doi: 10.1111/maps.13001. Parker, T. J., Saunders, R. S., and Schneeberger, D. M., 1989. Transitional morphology in the west Deuteronilus Mensae region of Mars: Implications for modification of the lowland/upland boundary. Icarus, 82, 111-145. Parker, T. J., Gorsline, D. S., Saunders, R. S., Pieri, D., and Schneeberger, D. M., 1993. Coastal geomorphology of the martian northern plains. J. Geophys. Res., 98, 11,061-11,078. Phillips, R. J., and 24 colleagues, 2008. Mars north polar deposits: stratigraphy, age, and geodynamical response. Science, 320, no. 5880, 1182–1185, http://dx.doi.org/10.1126/science.1157546. Plaut, J. J. and 24 colleagues, 2007. Subsurface radar sounding of the south polar layered deposits of Mars. Science, 316, 92-9. DOI: 10.1126/science.1139672. Plaut, J. J., Safaeinili, A., Holt, J. W., Phillips, R. J., Head, J. W., Seu, R., Putzig, N. E., and Frigeri, A.,2009. Radar evidence for ice in lobate debris aprons in the mid-northern latitudes of Mars. Geophys. Res. Lett., 36, L2203, doi: 10.1029/2008GL036379. Ramirez, R. M., and Craddock, R, A., 2018. The geological and climatological case for a warmer and wetter early Mars. Nature Geoscience 11, 230-237, doi.org/10.1038/s41561-018-0093-9. Rodriguez, J. A., Fairen, A. G., Tanaka, K. L., Zarroca, M., Linares, R., Platz, T., Komatsu, G., Miyamoto, H., Kargel, J. S., Yan, J., Gulick, V., Higuchi, K., Baker, V.R. and Glines, N. (2016). Tsunami waves extensively resurfaced the shorelines of an early Martian ocean. Scientific Report s, Article 25106. Ruiz, J., 2014. The early heat loss evolution of Mars and their implicaitons for internal and environmental history. Scientific Reports 4, Article 4338. doi:10.1038/srep04338. Ruiz, J., McGovern, P, Jimenez-Diaz , A., Lopez , V., Williams, J., Hahn, B., and Tejero , R., 2011. The thermal evolution of Mars as constrained by paleo-heat flows. Icarus, 215, 508-517. Russell, P.S., Head, J.W., 2007. The Martian hydrologic system: multiple recharge centers at large volcanic provinces and the contribution of snowmelt to outflow channel activity. Planet. Space Sci. Planet Mars II, 55, 315–332. doi:10.1016/j.pss.2006.03.010. Segura, T. L., Toon, O. B. and Colaprete, A. 2008. Modeling the environmental effects of moderate-sized impacts on Mars. J. Geophys. Res., 113, doi:10.1029.2008/JE003147. Seu, R., Kempf, S. D., Choudhary, P., Young, D. A., Putzig, N. E., Biccari, D., and Gim, Y., 2008. Radar sounding evidence for buried glaciers in the southern mid-latitudes of Mars. Science, 322, 12351238, doi: 10.1126/science.1164246. Smith, D. E., Zuber, M. T., Frey, H. V., Garvin, J. B., Head, J. W., Muhleman, D. O., Pettengill, G. H., Phillips, R. J., Solomon, S. C., Zwally, H. J., Banerdt, W. B. and Duxbury, T. C., 1998. Topography of the northern hemisphere of Mars from the Mars Orbiter Laser Altimeter,. Science, 279, 16861692. Smith, D. E. and 19 colleagues, 1999. The global topography of Mars and implications for surface evolution. Science 286, 94-97. doi: 10.1126/science.284.5419.1495. Smith, P.H. and 36 colleagues,2009. H2O at the Phoenix landing site. Science, 325, 58-61. doi: 10.1126/science.1172339. Stevenson, D. J., Spohn. T. and Schubert, G.,1983. Magnetism and thermal evolution of the terrestrial planets. Icarus, 54, 466-489. Tanaka, K.L., Skinner, J. A., Dohm, J. M., Rossman, P. I., Kolb, E. J., Fortezzo, C. M., Platz, T., Gregory, G. M. and Hare, T. M.,2014. Geologic Map of Mars. U. S. Geol. Survey, Scientific Inv. Map 3292.
ACCEPTED MANUSCRIPT 21
AN US
CR IP T
Tanaka, K. L., Skinner, J. A., and Hare, T. N., 2005. Geologic map of the northern plains of Mars. U. S. Geol. Survey, Scientific Inv. Map 2888. Thompson, B. J. and 7 others, 2011. Constraints on the origin and evolution of the central mound in Gale Crater using Mars Reconnaisance Orbiter data. Icarus, 214, 413-432. Turbet, M., Forget, F., Head, J. W., and Wordsworth, R., 2017. 3D modelling of the climatic impact of outflow channel formation events on early Mars. Icarus, 288, 10-36, doi: 10.1016/j.icarus.2017.01.024. Usui, T., C. Alexander, J. Wang, J. I. Simon and J. H. Jones, 2012. Origin of water and mantle-crust interactions on Mars inferred from the hydrogen isotopes and volatile elements of olivine-hosted melt inclusions of primitive shergottites. Earth Planet. Sci. Lett., 357-358, 119129. DOI:10.1016/j.epsl.2012.09.008. Villanueva, G.I., , Mumma, M. J., Novak, R. E., Kaufl, H. U., hartogh, P., Emcrenaz, T., Tokunaga, A., Khayat, A., and Smith A. D. , 2015. Strong wter isotopic anomalies in the martian atmosphere: Probing current and ancient reservoirs. Science, 348, 218-221. Yung, Y.L., Wen, J. S., Pinto, J. P., Pierce, K.K., Allen, M. and Paulson, S.,1988. HDO in the martian atmosphere: Implications for the abundance of crustal water. Icarus, 76, 146-159. Zuber, M. T., and 15 colleagues, 2000. Internal structure and early thermal evolution of Mars from Mars Global Surveyor. Science, 287, 1788-1799.
AC
CE
PT
ED
M
Figures.
ACCEPTED MANUSCRIPT
CE
PT
ED
M
AN US
CR IP T
22
Figure 1. Section of the Tanaka et al. (2014) geologic map of the northern hemisphere with the -3650 m
AC
contour superimposed (sinuous black line). The contour mostly follows the outer boundary of the Vastitas Borealis Formation (VBF). Where the contour is colored red, as northwest of Elysium and in Arcadia Planitia, the boundary is buried by younger units.
ACCEPTED MANUSCRIPT
AN US
CR IP T
23
M
Figure 2. The outer contact of the Vastitas Borealis Formation at 20N, 120E. The sharp, easily
AC
CE
PT
ED
recognizable contact can be traced at a constant elevation for well over 2000 km. The VBF is in the upper half of the image. Its southern boundary is marked by small convex outward lobes, interpreted here as a depositional boundary formed by the last major flood that entered the basin. The prominent crater in the lower left is 17 km across (THEMIS day).
ACCEPTED MANUSCRIPT
AN US
CR IP T
24
AC
CE
PT
ED
M
Figure 3. The Chryse basin between 300-360 deg. E and 10-50 deg. N. The -3650 m contour around the basin traces numerous sharp breaks in slope between the uplands and the plains and around islands in the flooded areas. The contour here follows erosional features cut by the large floods entering the basin from the south and west. The VBF boundary is further to the northeast (MOLA).
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
M
AN US
CR IP T
25
ACCEPTED MANUSCRIPT 26
AC
CE
PT
ED
M
AN US
CR IP T
Figure 4. Schematic diagram showing the proposed scenario for formation and elimination of the Hesperian ice ocean. Top: Floods that cut the large outflow channels enter the northern basin and form temporary lakes that rapidly freeze. Successive floods build a sequence of ice layers up to the -3650 contour which marks the edge of the last large flood. Bottom: After the flooding era the ice slowly sublimates, some being lost to space and some being redistributed to form the polar layered deposits and other near-surface ice deposits.
Figure 5. Typical result of modeling the evolution of D/H as described in the text. Here the exchangeable inventory is 30 m GEL and the present day loss rate is 30 m. GEL in 4 b.y. Curves for two different values of the present polar D/H show how the D/H of the exchangeable reservoir may have evolved over time.
ACCEPTED MANUSCRIPT
ED
M
AN US
CR IP T
27
AC
CE
PT
Figure 6. Estimated losses to space for different values of the present loss rates. The losses are corrected for earlier EUV enhancements. The colored areas show the measured range of 3.6-25 m GEL (Jakosky et al., 2018). The darker area indicates where loss rates fall short of those required to explain the doubling of D/H since the mid-Hesperian. The upper curve is for a present loss rate of 49 m GEL in 4.2 b.y., that required to eliminate a 110 m GEL ocean assuming a 30 m GEL present inventory and earlier EUV enhancements.