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Dark slope streak

December 18, 2023

Dark slope streaks are narrow, avalanche-like features common on dust-covered slopes in the equatorial regions of Mars.[2] They form in relatively steep terrain, such as along escarpments and crater walls.[3] Although first recognized in Viking Orbiter images from the late 1970s,[4][5] dark slope streaks were not studied in detail until higher-resolution images from the Mars Global Surveyor (MGS) and Mars Reconnaissance Orbiter (MRO) spacecraft became available in the late 1990s and 2000s.[1][6]

Slope streaks in Acheron Fossae in 2010
Dark slope streaks in Arabia Terra as seen by Mars Orbital Camera (MOC) on Mars Global Surveyor spacecraft. The darkest streaks are only about 10% darker than their surroundings. The greater apparent contrast in the image is due to contrast enhancement[1] Image is 1.65 km (1 mi) across. North is at bottom.

The physical process that produces dark slope streaks is still uncertain. They are most likely caused by the mass movement of loose, fine-grained material on oversteepened slopes (i.e., dust avalanches).[1][7][8] The avalanching disturbs and removes a bright surface layer of dust to expose a darker substrate.[9] The role that water and other volatiles plays, if any, in streak formation is still debated.[10] Slope streaks are particularly intriguing because they are one of the few geological phenomena that can be observed occurring on Mars in the present day.[11][12][13] [14] [15]

Nature of streaks on Mars edit

Dark slope streaks are albedo features. They appear to the eye as a brightness difference between the streak and the lighter-toned background slope. Usually no topographic relief is visible to distinguish the streak from its surroundings, except in the very highest resolution (<1 m/pixel) images.[6] In many cases, the original surface texture of the slope is preserved and continuous across the streak, as though unaffected by events involved in dark streak formation (pictured left). The overall effect is equivalent in appearance to a partial shadow cast down the sloping surface.[1] These observations indicate that whatever process forms the streaks, it affects only the very thinnest layer at the surface. Slope streaks are only about 10% darker than their surroundings but often appear black in images because the contrast has been enhanced (stretched).[16]

 
Dark slope streaks often do not affect the underlying texture of the slope on which they form, indicating that the disturbance causing the streak is superficial. Image is portion of MOC-N/A frame M09/00039, based on Sullivan et al., 2001, p. 23,612, Fig. 5a. The streak here is 1.3 km long.

Albedo features cover the Martian surface at a wide variety of scales. They make up the classical light and dark marking seen on Mars through telescopes. (See Classical albedo features on Mars.) The markings are caused by differing proportions of dust covering the surface. Martian dust is bright reddish ochre in color, while the bedrock and soil (regolith) is dark gray (the color of unaltered basalt). Thus, dusty areas on Mars appear bright (high albedo), and surfaces with a high percentage of rocks and rock fragments are generally dark (low albedo).[17] Most albedo features on Mars are caused by winds, which clear some areas of dust, leaving behind a darker lag. In other areas, dust is deposited to produce a bright surface. The selective removal and deposition of dust is most conspicuous around impact craters and other obstacles where a variety of streaks (wind tails) and blotches are formed.[18]

Dark slope streaks are relatively small features. (See A in Photo Gallery.) They differ from larger albedo features in being produced by gravity rather than wind, although wind may contribute to their initial formation.[1][16][19] (See B in Photo Gallery.) The cause of the darkening is uncertain. The particle sizes involved are believed to be very small (sand, silt, and clay-sized particles). No clasts large enough to be imaged are present, and the underlying bedrock slope is never exposed ( i.e., dust is avalanching on a surface of dust).[20] Apparently, other optical, mechanical, or chemical properties are involved in producing the darker tone.

Dark slope streaks commonly share the same slope with other slope streaks of varying tones. The darkest streaks are presumed to be youngest; they have margins that are more sharply defined than streaks that are not as dark.[21] This relationship suggests that streaks lighten and become more diffuse with age,[5] probably because they become covered with fresh dust falling from the atmosphere.[6][12] Faded dark slope streaks should not be confused with bright slope streaks (discussed below). Dust storms are common on Mars. At times the whole planet is enveloped in a dust storm, as shown in the pictures below.

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    Mars without a dust storm in June 2001 (on left) and with a global dust storm in July 2001 (on right), as seen by Mars Global Surveyor

Morphology and occurrence edit

 
Dark slope streaks are often fan-shaped with multiple fingers (digitation) at their downslope ends. Image is from the HiRISE camera on the Mars Reconnaissance Orbiter.
 
Slope streaks[22]

At moderate resolutions (20–50 m/pixel), dark slope streaks appear as thin, parallel filaments aligned downslope along crater rims and escarpments. They are often straight but may also be curved or sigmoid in shape. (See C in Photo Gallery.) Closer up, dark slope streaks typically have elongated, fan-like shapes (pictured right). They range from about 20 to 200 meters in width and are generally several hundred meters to over 1,000 meters long. Dark slope streaks exceeding 2 kilometers in length are uncommon; most terminate on slope and do not extend further out on to level terrain.[1][2][16]

A streak commonly starts at a single point (apex) high on the slope. The apex is often associated with an isolated small ridge, knob, or other area of local steepening.[1] In high-resolution images, a tiny impact crater is sometimes visible at the apex.[6] Slope streaks widen downslope from the apex in a triangular fashion, usually reaching their maximum widths short of the halfway point of their lengths.[1] A single slope streak can split into two separate streaks around an obstacle or form an anastamosing (braided) pattern. (See D and E in Photo Gallery.) Slope streaks commonly develop multiple fingers (digitation) at their downslope ends.[6]

 
Map of Mars showing that dark slope streaks (brown) occur in dust-covered, equatorial regions. Pink areas are the locations of Martian Gullies and gully deposits. The geographical distribution indicates that gullies and slope streaks are different phenomena.

Images from the High Resolution Imaging Science Experiment (HiRISE) on MRO have shown that many slope streaks have relief, contrary to earlier descriptions in which no topographic distinction could be seen between the streaked and adjacent, non-streaked surface. The streaked surface is typically about 1 m lower than the non-streaked surface. This relief is only visible in maximum resolution images under optimal viewing conditions.[2][6][23]

Dark slope streaks are most common in the equatorial regions of Mars, particularly in Tharsis, Arabia Terra, and Amazonis Planitia[24] (pictured left). They occur between latitudes 39°N and 28°S. At their northern limits, they appear preferentially on warmer, south facing slopes. Curiously, slope streaks are also associated with areas that reach peak temperatures of 275K (2 °C), a temperature close to the triple point of water on Mars. This relationship has led some researchers to suggest that liquid water is involved in dark slope streak formation.[2][16]

Dark slope streaks do not appear to correlate with elevation or areas of specific bedrock geology. They occur on a wide range of slope textures, including surfaces that are smooth, featureless, and presumably young, as well as older, heavily cratered slopes.[1] However, they are always associated with areas of high surface roughness, high albedo, and low thermal inertia, properties that indicate steep slopes covered with a lot of dust.[3][5][21][25]

It has been suggested that streaks could form when accumulations of dry ice start subliming right after sunrise. Nighttime CO2 frost is widespread in low latitudes.[26]

Formation mechanism edit

 
Annotated image of Tharsis Tholus dark streak, as seen by Hirise. It is located in the middle left of this picture. Tharsis Tholus is just off to the right.

Researchers have proposed a number of mechanisms for dark slope streak formation. The most widely held view is that the streaks are the result of dust avalanches produced by dry granular flow[27] on oversteepened slopes. Dust avalanches resemble loose snow avalanches on Earth. Loose snow avalanches occur when snow accumulates under cold, nearly windless conditions, producing a dry, powdery snow with little cohesion between individual snow crystals.[1] The process produces a very shallow trough (slough) on the surface of the snow, which from a distance appears slightly darker in tone than the rest of the slope.

Other models involve water, either in the form of spring discharges,[28] wet debris flows,[5] or seasonal percolation of chloride-rich brines.[11] Using data from the Mars Odyssey Neutron Spectrometer, researchers found that slope streaks in the Schiaparelli basin occur in areas predicted to yield between 7.0 and 9.0 weight percent Water Equivalent Hydrogen (WEH) in contrast to typical background values of less than 4% WEH. This relationship suggests a connection between high WEH percentages and the occurrence of dark slope streaks.[29] However, any process that requires voluminous amounts of water (e.g., spring discharges) seems unlikely because of the overall thermodynamic instability of liquid water on Mars.[12]

Another model proposes that dark slope streaks are produced by ground-hugging density currents of dry dust lubricated by carbon dioxide (CO2) gas. In this scenario, a small initial slump at the surface releases CO2 gas adsorbed onto subsurface grains. This release produces a gas-supported dust flow that moves as a tenuous density current downslope. This mechanism may help explain slope streaks that are unusually long.[30][31]

Some observations suggest that dark slope streaks can be triggered by impacts. Pictures acquired by CTX in 2007 and 2010 showed a new streak appeared in the aureole of Olympus Mons. A follow-up image from HiRISE showed that a new crater at the top of the streak. The researchers concluded that the impact triggered the new slope streak.[32] Another streak connected with an impact was found in the Arabia quadrangle.[33]

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    New streak that was caused by a recent impact that created a small crater, as seen by HiRISE. Location is the Arabia quadrangle.

Research, published in January 2012 in Icarus, found that dark streaks were initiated by airblasts from meteorites traveling at supersonic speeds. The team of scientists was led by Kaylan Burleigh, an undergraduate at the University of Arizona. After counting some 65,000 dark streaks around the impact site of a group of 5 new craters, patterns emerged. The number of streaks was greatest closer to the impact site. So, the impact somehow probably caused the streaks. Also, the distribution of the streaks formed a pattern with two wings extending from the impact site. The curved wings resembled scimitars, curved knives. This pattern suggests that an interaction of airblasts from the group of meteorites shook dust loose enough to start dust avalanches that formed the many dark streaks. At first it was thought that the shaking of the ground from the impact caused the dust avalanches, but if that was the case the dark streaks would have been arranged symmetrically around the impacts, rather than being concentrated into curved shapes.

The crater cluster lies near the equator 510 miles) south of Olympus Mons, on a type of terrain called the Medusae Fossae formation. The formation is coated with dust and contains wind-carved ridges called yardangs. These yardangs have steep slopes thickly covered with dust, so when the sonic boom of the airblast arrived from the impacts dust started to move down the slope. Using photos from Mars Global Surveyor and HiRISE camera on NASA's Mars Reconnaissance Orbiter, scientists have found about 20 new impacts each year on Mars. Because the spacecraft have been imaging Mars almost continuously for a span of 14 years, newer images with suspected recent craters can be compared to older images to determine when the craters were formed. Since the craters were spotted in a HiRISE image from February 2006, but were not present in a Mars Global Surveyor image taken in May 2004, the impact occurred in that time frame.

The largest crater in the cluster is about 22 meters (72 feet) in diameter with close to the area of a basketball court. As the meteorite traveled through the Martian atmosphere it probably broke up; hence a tight group of impact craters resulted. Dark slope streaks have been seen for some time, and many ideas have been advanced to explain them. This research may have finally solved this mystery.[34][35][36]

  •  
    Image indicates crater cluster and curved lines formed by airblast from meteorites. Meteorites caused airblast which caused dust avalanches on steep slopes. Image is from HiRISE.
  •  
    Close up of previous image along light/dark boundary. Dark line in middle of image shows border between light and dark area of curved lines. Green arrows show high areas of ridges. Loose dust moved down steep slopes when it felt the airblast from meteorite strikes. Image is from HiRISE.

Dust devils have even been observed to start the formation of dark slope streaks.[37] [38]

Formation rate edit

 
New slope streaks formed near Apollinaris Mons between February 1998 and November 1999, as seen by Mars Orbital Camera (MOC).

Slope streaks are one of the few geomorphic features forming on the surface of present-day Mars. New streaks were first identified by comparing images from the Viking Orbiters of the 1970s to images of the same locations taken by the MGS Mars Orbiter Camera (MOC) in the late 1990s. The presence of new streaks showed that slope streaks are actively forming on Mars, on at least annual to decade-long timescales.[20][39] A later, statistical treatment using overlapping MOC images spaced days to several years apart showed that slope streaks may form on Mars at a rate of about 70 per day. If accurate, this rate suggests that slope streaks are the most dynamic geologic features observed on the surface of Mars.[12]

Dark slope streaks fade and disappear at a much slower rate than new ones appear. Most streaks identified in Viking images are still visible after decades, although a few have vanished. Researchers infer that streaks appear at a rate 10 times faster than they disappear, and that the number of slope streaks on Mars has increased in the last three decades. This imbalance is unlikely to have persisted for geologically significant periods of time. One possible solution to the imbalance is that streaks last for centuries, but are wiped clean en masse after extremely rare but fierce dust storms (storms of a magnitude not observed on Mars since Viking). After the storm subsides, a thick layer of fresh dust is deposited to begin a new cycle of streak formation.[12][19] A recent study published in Icarus found that they last about 40 years. The researchers looked at a region in Lycus Sulci with Viking images and with CTX images from the Mars Reconnaissance Orbiter. The ones first observed with Viking have all gone, but have been replaced with new ones.[40]

Similar and related features edit

Dark slope streaks occur in association with or superficially resemble a number of other small-scale, slope-related features on Mars. These include bright slope streaks, avalanche scars, and recurring slope lineae. Water tracks are features that occur in the polar regions of Earth. They resemble dark slope streaks and recurring slope lineae, but have not yet been described on Mars. Many of the slope features on Mars may originate through a continuum of processes with dry mass wasting and minor fluvial (water-related) activity occupying opposite endpoints.[9] Gullies are another feature common on slopes in the mid-latitude southern hemisphere of Mars They have received much attention in the literature but are not discussed here.

Bright slope streaks edit

Bright slope streaks are streaks that have a lighter tone (about 2%) than their surroundings.[1] (See F in Photo Gallery.) They are much rarer than dark slope streaks, but both types of streaks have similar morphologies and occur in the same regions of Mars. Evidence suggests that bright slope streaks are older than dark slope streaks. New bright slope streaks have never been observed, and dark slope streaks can be seen overlying bright slope streaks in some images, indicating that the former are younger than the latter. It is likely that bright slope streaks form from old dark slope streaks that have transitioned past a partially faded stage. This supposition is supported by geographical evidence indicating that bright slope streaks are slightly more common in regions where the formation rate of new dark slope streaks is low. In other words, areas with relatively many bright streaks tend to be less active and contain a higher population of old dark streaks.[19]

Avalanche scars edit

Areas with abundant slope streaks also contain an apparently distinct class of avalanche scars. The scars resemble slope streaks in morphology and size. (See G in Photo Gallery) They are typically several meters deep and hundreds of meters long. They begin at a single point (sometimes a small, barely resolved impact crater) high on a slope. The edges radiate downslope in a triangular fashion. In about half of the documented examples, a low-lying mound of debris is visible at the downslope end. Originally called "meters-thick avalanche scars," these features were thought to be distinct from slope streaks. However, higher-resolution images from the HiRISE instrument on MRO suggest that meters-thick avalanche scars and slope streaks are related and part of a continuum of active mass wasting features formed by dust avalanches.[6][41]

Recurring slope lineae (warm-season flows) edit

Main article: Seasonal flows on warm Martian slopes

In the summer of 2011, a paper appeared in Science[42] describing a new class of slope features with characteristics that suggest formation by seasonal releases of liquid water. (See H and I in Photo Gallery.) Called "recurring slope lineae" (RSL),[43] the features received a considerable amount of media attention.[44][45] RSLs are narrow (0.5 to 5 meters) dark markings that preferentially occur on steep, equator-facing slopes in the southern hemisphere between latitudes 48°S to 32°S. Repeat HiRISE images show that the markings appear and grow incrementally during warm seasons and fade in cold seasons.[42] RSLs bear only a superficial resemblance to dark slope streaks. They are much smaller in width and have a different pattern of geographic occurrence and slope properties than dark slope streaks.[46] RSLs seem to occur on bedrock slopes with seasonally high surface temperatures of 250–300K (-23–27 °C). These location may favor the flow of briney fluids emerging from seeps at certain times of the Martian year.[42] Unlike RSLs, dark slope streaks appear to occur sporadically throughout the Martian year, and their triggering seems unrelated to season or large regional events.[47]

Water tracks edit

Water tracks are little-studied slope features common in permafrost-dominated terrains in the arctic and Antarctic regions of Earth. They are zones of enhanced soil moisture that route water downslope over the top of the permanently frozen ground just below the surface (ice table). Although water tracks have not been specifically identified on Mars, several researchers have noted their morphological and spectroscopic similarity to Martian slope streaks.[48] Like dark slope streaks, water tracks are narrow, sublinear features elongated in the downslope direction. They typically display a slight darkness relative to their surroundings and show little or no detectable relief. During peak flow conditions, they appear as damp, darkened, patches of soil that are generally less than 60 m wide and several hundred meters long.[11] The dark surface discoloration vanishes in frozen water tracks during winter, rendering them nearly undetectable.[48]

Photo gallery edit

Dark streaks and related features appear in the images below. To see the features described in the caption and text, it may be necessary to enlarge the image by clicking on it.

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    A. Dark slope streaks are the tiny, linear albedo features along the SE wall of the crater. Compare with the far larger, wind-related albedo feature (oval patch at center top of image). This image is a THEMIS VIS from the Mars Odyssey spacecraft. It is about 25 km wide. North is at top.
  •  
    B. This dark slope streak may have been initiated by winds from dust devil. A thin dust devil track is visible across the apex of the slope streak. This Mars Reconnaissance Orbiter (MRO) HiRISE image is 1.8 km across and based on Schorghofer et al., 2007, p. 136, Fig. 5.
  •  
    C. Dark streaks in Diacria quadrangle, as seen by the Mars Orbiter Camera (MOC) on Mars Global Surveyor (MGS).
  •  
    D. Dark slope streaks in Phlegra Dorsa region as seen by MOC. The streak near the center of image has been diverted around a small hill. The image is about 3 km (1.9 mi) across.
  •  
    E. Braided (anastomosing) slope streak in Lycus Sulci region as seen by MOC. The morphology resembles features produced by fuidized flow. The image is about 3 km (1.9 mi) across.
  •  
    F. Both dark and bright slope sreaks occur together on the wall of this impact crater in Arabia Terra as seen by MOC. Photometric analysis shows that the brightness of the streaks is inherent and not due to lighting conditions or viewing geometry.[1]
  •  
    G. Shallow avalanche scars associated with dark slope streak. The slope streak has the same sharp apex and triangular-faceted morphology as the scars, suggesting that both types of features have a similar origin. Image is from HiRISE.
  •  
    H. Recurring slope lineae as seen by HiRISE.
  •  
    I. Seasonal Dark Flows, "Recurring Slope Linae" (RSL), on Martian slopes (2 November 2007).[43]
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    Dark slope streaks near the top of a pedestal crater, as seen by HiRISE under the HiWish program.
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    Dark slope streaks and layers near a pedestal crater, as seen by HiRISE under the HiWish program.
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    Young and old dark streaks, as seen by HiRISE under HiWish program. Location is Diacria quadrangle.
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    Dark slope streaks, as seen by HiRISE under the HiWish program Arrows show how boulders affected the shape of the streaks.
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    Dark slope streaks, as seen by HiRISE under the HiWish program Arrows show how boulders affected the shape of the streaks.
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    Wide view of mesas with dark slope streaks, as seen by HiRISE under HiWish program
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    Large group of dark slope streaks along a mesa wall, as seen by HIRISE
  •  
    Close view of end of dark slope streaks, as seen by HiRISE
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    Dark slope streaks along a mesa wall, as seen by HIRISE Picture is about 1 km across.
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    Close view of end of dark slope streaks, as seen by HiRISE

References edit

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  46. ^ McEwen, A. Ojha L.; Dundas C.; Mattson, S.; Byrne S.; Wray J.; Cull S.; Murchie S. (2011). Transient Slope Lineae: Evidence for Summertime Briny Flows on Mars? 42nd Lunar and Planetary Science Conference, Abstract #2314. http://www.lpi.usra.edu/meetings/lpsc2011/pdf/2314.pdf.
  47. ^ Schorghofer, N.; King, C.M. (2011). Sporadic Formation of Slope Streaks on Mars. Icarus, 216(1), 159-168.
  48. ^ a b Levy, J. S.; Fountain, A. G. (2011). "Water Tracks" in the McMurdo Dry Valleys, Antarctica: A Permafrost-Based Hydrological System Supporting Complex Biological and Geochemical Processes in a Mars-Analog Environment. 42nd Lunar and Planetary Science Conference, Abstract #1210. http://www.lpi.usra.edu/meetings/lpsc2011/pdf/1210.pdf.

Further reading edit

  • Barlow, N.G. (2008). Mars: An Introduction to Its Interior, Surface, and Atmosphere; Cambridge University Press: Cambridge, UK, ISBN 978-0-521-85226-5.
  • Hartmann, William, K. (2003). A Traveler’s Guide to Mars: The Mysterious Landscapes of the Red Planet; Workman: New York, ISBN 0-7611-2606-6.

December 18, 2023
dark, slope, streak, narrow, avalanche, like, features, common, dust, covered, slopes, equatorial, regions, mars, they, form, relatively, steep, terrain, such, along, escarpments, crater, walls, although, first, recognized, viking, orbiter, images, from, late,. Dark slope streaks are narrow avalanche like features common on dust covered slopes in the equatorial regions of Mars 2 They form in relatively steep terrain such as along escarpments and crater walls 3 Although first recognized in Viking Orbiter images from the late 1970s 4 5 dark slope streaks were not studied in detail until higher resolution images from the Mars Global Surveyor MGS and Mars Reconnaissance Orbiter MRO spacecraft became available in the late 1990s and 2000s 1 6 Slope streaks in Acheron Fossae in 2010Dark slope streaks in Arabia Terra as seen by Mars Orbital Camera MOC on Mars Global Surveyor spacecraft The darkest streaks are only about 10 darker than their surroundings The greater apparent contrast in the image is due to contrast enhancement 1 Image is 1 65 km 1 mi across North is at bottom The physical process that produces dark slope streaks is still uncertain They are most likely caused by the mass movement of loose fine grained material on oversteepened slopes i e dust avalanches 1 7 8 The avalanching disturbs and removes a bright surface layer of dust to expose a darker substrate 9 The role that water and other volatiles plays if any in streak formation is still debated 10 Slope streaks are particularly intriguing because they are one of the few geological phenomena that can be observed occurring on Mars in the present day 11 12 13 14 15 Contents 1 Nature of streaks on Mars 2 Morphology and occurrence 3 Formation mechanism 4 Formation rate 5 Similar and related features 5 1 Bright slope streaks 5 2 Avalanche scars 5 3 Recurring slope lineae warm season flows 5 4 Water tracks 6 Photo gallery 7 References 8 Further readingNature of streaks on Mars editDark slope streaks are albedo features They appear to the eye as a brightness difference between the streak and the lighter toned background slope Usually no topographic relief is visible to distinguish the streak from its surroundings except in the very highest resolution lt 1 m pixel images 6 In many cases the original surface texture of the slope is preserved and continuous across the streak as though unaffected by events involved in dark streak formation pictured left The overall effect is equivalent in appearance to a partial shadow cast down the sloping surface 1 These observations indicate that whatever process forms the streaks it affects only the very thinnest layer at the surface Slope streaks are only about 10 darker than their surroundings but often appear black in images because the contrast has been enhanced stretched 16 nbsp Dark slope streaks often do not affect the underlying texture of the slope on which they form indicating that the disturbance causing the streak is superficial Image is portion of MOC N A frame M09 00039 based on Sullivan et al 2001 p 23 612 Fig 5a The streak here is 1 3 km long Albedo features cover the Martian surface at a wide variety of scales They make up the classical light and dark marking seen on Mars through telescopes See Classical albedo features on Mars The markings are caused by differing proportions of dust covering the surface Martian dust is bright reddish ochre in color while the bedrock and soil regolith is dark gray the color of unaltered basalt Thus dusty areas on Mars appear bright high albedo and surfaces with a high percentage of rocks and rock fragments are generally dark low albedo 17 Most albedo features on Mars are caused by winds which clear some areas of dust leaving behind a darker lag In other areas dust is deposited to produce a bright surface The selective removal and deposition of dust is most conspicuous around impact craters and other obstacles where a variety of streaks wind tails and blotches are formed 18 Dark slope streaks are relatively small features See A in Photo Gallery They differ from larger albedo features in being produced by gravity rather than wind although wind may contribute to their initial formation 1 16 19 See B in Photo Gallery The cause of the darkening is uncertain The particle sizes involved are believed to be very small sand silt and clay sized particles No clasts large enough to be imaged are present and the underlying bedrock slope is never exposed i e dust is avalanching on a surface of dust 20 Apparently other optical mechanical or chemical properties are involved in producing the darker tone Dark slope streaks commonly share the same slope with other slope streaks of varying tones The darkest streaks are presumed to be youngest they have margins that are more sharply defined than streaks that are not as dark 21 This relationship suggests that streaks lighten and become more diffuse with age 5 probably because they become covered with fresh dust falling from the atmosphere 6 12 Faded dark slope streaks should not be confused with bright slope streaks discussed below Dust storms are common on Mars At times the whole planet is enveloped in a dust storm as shown in the pictures below nbsp Mars without a dust storm in June 2001 on left and with a global dust storm in July 2001 on right as seen by Mars Global SurveyorMorphology and occurrence edit nbsp Dark slope streaks are often fan shaped with multiple fingers digitation at their downslope ends Image is from the HiRISE camera on the Mars Reconnaissance Orbiter nbsp Slope streaks 22 At moderate resolutions 20 50 m pixel dark slope streaks appear as thin parallel filaments aligned downslope along crater rims and escarpments They are often straight but may also be curved or sigmoid in shape See C in Photo Gallery Closer up dark slope streaks typically have elongated fan like shapes pictured right They range from about 20 to 200 meters in width and are generally several hundred meters to over 1 000 meters long Dark slope streaks exceeding 2 kilometers in length are uncommon most terminate on slope and do not extend further out on to level terrain 1 2 16 A streak commonly starts at a single point apex high on the slope The apex is often associated with an isolated small ridge knob or other area of local steepening 1 In high resolution images a tiny impact crater is sometimes visible at the apex 6 Slope streaks widen downslope from the apex in a triangular fashion usually reaching their maximum widths short of the halfway point of their lengths 1 A single slope streak can split into two separate streaks around an obstacle or form an anastamosing braided pattern See D and E in Photo Gallery Slope streaks commonly develop multiple fingers digitation at their downslope ends 6 nbsp Map of Mars showing that dark slope streaks brown occur in dust covered equatorial regions Pink areas are the locations of Martian Gullies and gully deposits The geographical distribution indicates that gullies and slope streaks are different phenomena Images from the High Resolution Imaging Science Experiment HiRISE on MRO have shown that many slope streaks have relief contrary to earlier descriptions in which no topographic distinction could be seen between the streaked and adjacent non streaked surface The streaked surface is typically about 1 m lower than the non streaked surface This relief is only visible in maximum resolution images under optimal viewing conditions 2 6 23 Dark slope streaks are most common in the equatorial regions of Mars particularly in Tharsis Arabia Terra and Amazonis Planitia 24 pictured left They occur between latitudes 39 N and 28 S At their northern limits they appear preferentially on warmer south facing slopes Curiously slope streaks are also associated with areas that reach peak temperatures of 275K 2 C a temperature close to the triple point of water on Mars This relationship has led some researchers to suggest that liquid water is involved in dark slope streak formation 2 16 Dark slope streaks do not appear to correlate with elevation or areas of specific bedrock geology They occur on a wide range of slope textures including surfaces that are smooth featureless and presumably young as well as older heavily cratered slopes 1 However they are always associated with areas of high surface roughness high albedo and low thermal inertia properties that indicate steep slopes covered with a lot of dust 3 5 21 25 It has been suggested that streaks could form when accumulations of dry ice start subliming right after sunrise Nighttime CO2 frost is widespread in low latitudes 26 Formation mechanism edit nbsp Annotated image of Tharsis Tholus dark streak as seen by Hirise It is located in the middle left of this picture Tharsis Tholus is just off to the right Researchers have proposed a number of mechanisms for dark slope streak formation The most widely held view is that the streaks are the result of dust avalanches produced by dry granular flow 27 on oversteepened slopes Dust avalanches resemble loose snow avalanches on Earth Loose snow avalanches occur when snow accumulates under cold nearly windless conditions producing a dry powdery snow with little cohesion between individual snow crystals 1 The process produces a very shallow trough slough on the surface of the snow which from a distance appears slightly darker in tone than the rest of the slope Other models involve water either in the form of spring discharges 28 wet debris flows 5 or seasonal percolation of chloride rich brines 11 Using data from the Mars Odyssey Neutron Spectrometer researchers found that slope streaks in the Schiaparelli basin occur in areas predicted to yield between 7 0 and 9 0 weight percent Water Equivalent Hydrogen WEH in contrast to typical background values of less than 4 WEH This relationship suggests a connection between high WEH percentages and the occurrence of dark slope streaks 29 However any process that requires voluminous amounts of water e g spring discharges seems unlikely because of the overall thermodynamic instability of liquid water on Mars 12 Another model proposes that dark slope streaks are produced by ground hugging density currents of dry dust lubricated by carbon dioxide CO2 gas In this scenario a small initial slump at the surface releases CO2 gas adsorbed onto subsurface grains This release produces a gas supported dust flow that moves as a tenuous density current downslope This mechanism may help explain slope streaks that are unusually long 30 31 Some observations suggest that dark slope streaks can be triggered by impacts Pictures acquired by CTX in 2007 and 2010 showed a new streak appeared in the aureole of Olympus Mons A follow up image from HiRISE showed that a new crater at the top of the streak The researchers concluded that the impact triggered the new slope streak 32 Another streak connected with an impact was found in the Arabia quadrangle 33 nbsp New streak that was caused by a recent impact that created a small crater as seen by HiRISE Location is the Arabia quadrangle Research published in January 2012 in Icarus found that dark streaks were initiated by airblasts from meteorites traveling at supersonic speeds The team of scientists was led by Kaylan Burleigh an undergraduate at the University of Arizona After counting some 65 000 dark streaks around the impact site of a group of 5 new craters patterns emerged The number of streaks was greatest closer to the impact site So the impact somehow probably caused the streaks Also the distribution of the streaks formed a pattern with two wings extending from the impact site The curved wings resembled scimitars curved knives This pattern suggests that an interaction of airblasts from the group of meteorites shook dust loose enough to start dust avalanches that formed the many dark streaks At first it was thought that the shaking of the ground from the impact caused the dust avalanches but if that was the case the dark streaks would have been arranged symmetrically around the impacts rather than being concentrated into curved shapes The crater cluster lies near the equator 510 miles south of Olympus Mons on a type of terrain called the Medusae Fossae formation The formation is coated with dust and contains wind carved ridges called yardangs These yardangs have steep slopes thickly covered with dust so when the sonic boom of the airblast arrived from the impacts dust started to move down the slope Using photos from Mars Global Surveyor and HiRISE camera on NASA s Mars Reconnaissance Orbiter scientists have found about 20 new impacts each year on Mars Because the spacecraft have been imaging Mars almost continuously for a span of 14 years newer images with suspected recent craters can be compared to older images to determine when the craters were formed Since the craters were spotted in a HiRISE image from February 2006 but were not present in a Mars Global Surveyor image taken in May 2004 the impact occurred in that time frame The largest crater in the cluster is about 22 meters 72 feet in diameter with close to the area of a basketball court As the meteorite traveled through the Martian atmosphere it probably broke up hence a tight group of impact craters resulted Dark slope streaks have been seen for some time and many ideas have been advanced to explain them This research may have finally solved this mystery 34 35 36 nbsp Image indicates crater cluster and curved lines formed by airblast from meteorites Meteorites caused airblast which caused dust avalanches on steep slopes Image is from HiRISE nbsp Close up of previous image along light dark boundary Dark line in middle of image shows border between light and dark area of curved lines Green arrows show high areas of ridges Loose dust moved down steep slopes when it felt the airblast from meteorite strikes Image is from HiRISE Dust devils have even been observed to start the formation of dark slope streaks 37 38 Formation rate edit nbsp New slope streaks formed near Apollinaris Mons between February 1998 and November 1999 as seen by Mars Orbital Camera MOC Slope streaks are one of the few geomorphic features forming on the surface of present day Mars New streaks were first identified by comparing images from the Viking Orbiters of the 1970s to images of the same locations taken by the MGS Mars Orbiter Camera MOC in the late 1990s The presence of new streaks showed that slope streaks are actively forming on Mars on at least annual to decade long timescales 20 39 A later statistical treatment using overlapping MOC images spaced days to several years apart showed that slope streaks may form on Mars at a rate of about 70 per day If accurate this rate suggests that slope streaks are the most dynamic geologic features observed on the surface of Mars 12 Dark slope streaks fade and disappear at a much slower rate than new ones appear Most streaks identified in Viking images are still visible after decades although a few have vanished Researchers infer that streaks appear at a rate 10 times faster than they disappear and that the number of slope streaks on Mars has increased in the last three decades This imbalance is unlikely to have persisted for geologically significant periods of time One possible solution to the imbalance is that streaks last for centuries but are wiped clean en masse after extremely rare but fierce dust storms storms of a magnitude not observed on Mars since Viking After the storm subsides a thick layer of fresh dust is deposited to begin a new cycle of streak formation 12 19 A recent study published in Icarus found that they last about 40 years The researchers looked at a region in Lycus Sulci with Viking images and with CTX images from the Mars Reconnaissance Orbiter The ones first observed with Viking have all gone but have been replaced with new ones 40 Similar and related features editDark slope streaks occur in association with or superficially resemble a number of other small scale slope related features on Mars These include bright slope streaks avalanche scars and recurring slope lineae Water tracks are features that occur in the polar regions of Earth They resemble dark slope streaks and recurring slope lineae but have not yet been described on Mars Many of the slope features on Mars may originate through a continuum of processes with dry mass wasting and minor fluvial water related activity occupying opposite endpoints 9 Gullies are another feature common on slopes in the mid latitude southern hemisphere of Mars They have received much attention in the literature but are not discussed here Bright slope streaks edit Bright slope streaks are streaks that have a lighter tone about 2 than their surroundings 1 See F in Photo Gallery They are much rarer than dark slope streaks but both types of streaks have similar morphologies and occur in the same regions of Mars Evidence suggests that bright slope streaks are older than dark slope streaks New bright slope streaks have never been observed and dark slope streaks can be seen overlying bright slope streaks in some images indicating that the former are younger than the latter It is likely that bright slope streaks form from old dark slope streaks that have transitioned past a partially faded stage This supposition is supported by geographical evidence indicating that bright slope streaks are slightly more common in regions where the formation rate of new dark slope streaks is low In other words areas with relatively many bright streaks tend to be less active and contain a higher population of old dark streaks 19 Avalanche scars edit Areas with abundant slope streaks also contain an apparently distinct class of avalanche scars The scars resemble slope streaks in morphology and size See G in Photo Gallery They are typically several meters deep and hundreds of meters long They begin at a single point sometimes a small barely resolved impact crater high on a slope The edges radiate downslope in a triangular fashion In about half of the documented examples a low lying mound of debris is visible at the downslope end Originally called meters thick avalanche scars these features were thought to be distinct from slope streaks However higher resolution images from the HiRISE instrument on MRO suggest that meters thick avalanche scars and slope streaks are related and part of a continuum of active mass wasting features formed by dust avalanches 6 41 Recurring slope lineae warm season flows edit Main article Seasonal flows on warm Martian slopes In the summer of 2011 a paper appeared in Science 42 describing a new class of slope features with characteristics that suggest formation by seasonal releases of liquid water See H and I in Photo Gallery Called recurring slope lineae RSL 43 the features received a considerable amount of media attention 44 45 RSLs are narrow 0 5 to 5 meters dark markings that preferentially occur on steep equator facing slopes in the southern hemisphere between latitudes 48 S to 32 S Repeat HiRISE images show that the markings appear and grow incrementally during warm seasons and fade in cold seasons 42 RSLs bear only a superficial resemblance to dark slope streaks They are much smaller in width and have a different pattern of geographic occurrence and slope properties than dark slope streaks 46 RSLs seem to occur on bedrock slopes with seasonally high surface temperatures of 250 300K 23 27 C These location may favor the flow of briney fluids emerging from seeps at certain times of the Martian year 42 Unlike RSLs dark slope streaks appear to occur sporadically throughout the Martian year and their triggering seems unrelated to season or large regional events 47 Water tracks edit Water tracks are little studied slope features common in permafrost dominated terrains in the arctic and Antarctic regions of Earth They are zones of enhanced soil moisture that route water downslope over the top of the permanently frozen ground just below the surface ice table Although water tracks have not been specifically identified on Mars several researchers have noted their morphological and spectroscopic similarity to Martian slope streaks 48 Like dark slope streaks water tracks are narrow sublinear features elongated in the downslope direction They typically display a slight darkness relative to their surroundings and show little or no detectable relief During peak flow conditions they appear as damp darkened patches of soil that are generally less than 60 m wide and several hundred meters long 11 The dark surface discoloration vanishes in frozen water tracks during winter rendering them nearly undetectable 48 Photo gallery editDark streaks and related features appear in the images below To see the features described in the caption and text it may be necessary to enlarge the image by clicking on it nbsp A Dark slope streaks are the tiny linear albedo features along the SE wall of the crater Compare with the far larger wind related albedo feature oval patch at center top of image This image is a THEMIS VIS from the Mars Odyssey spacecraft It is about 25 km wide North is at top nbsp B This dark slope streak may have been initiated by winds from dust devil A thin dust devil track is visible across the apex of the slope streak This Mars Reconnaissance Orbiter MRO HiRISE image is 1 8 km across and based on Schorghofer et al 2007 p 136 Fig 5 nbsp C Dark streaks in Diacria quadrangle as seen by the Mars Orbiter Camera MOC on Mars Global Surveyor MGS nbsp D Dark slope streaks in Phlegra Dorsa region as seen by MOC The streak near the center of image has been diverted around a small hill The image is about 3 km 1 9 mi across nbsp E Braided anastomosing slope streak in Lycus Sulci region as seen by MOC The morphology resembles features produced by fuidized flow The image is about 3 km 1 9 mi across nbsp F Both dark and bright slope sreaks occur together on the wall of this impact crater in Arabia Terra as seen by MOC Photometric analysis shows that the brightness of the streaks is inherent and not due to lighting conditions or viewing geometry 1 nbsp G Shallow avalanche scars associated with dark slope streak The slope streak has the same sharp apex and triangular faceted morphology as the scars suggesting that both types of features have a similar origin Image is from HiRISE nbsp H Recurring slope lineae as seen by HiRISE nbsp I Seasonal Dark Flows Recurring Slope Linae RSL on Martian slopes 2 November 2007 43 nbsp Dark slope streaks near the top of a pedestal crater as seen by HiRISE under the HiWish program nbsp Dark slope streaks and layers near a pedestal crater as seen by HiRISE under the HiWish program nbsp Young and old dark streaks as seen by HiRISE under HiWish program Location is Diacria quadrangle nbsp Dark slope streaks as seen by HiRISE under the HiWish program Arrows show how boulders affected the shape of the streaks nbsp Dark slope streaks as seen by HiRISE under the HiWish program Arrows show how boulders affected the shape of the streaks nbsp Wide view of mesas with dark slope streaks as seen by HiRISE under HiWish program nbsp Large group of dark slope streaks along a mesa wall as seen by HIRISE nbsp Close view of end of dark slope streaks as seen by HiRISE nbsp Dark slope streaks along a mesa wall as seen by HIRISE Picture is about 1 km across nbsp Close view of end of dark slope streaks as seen by HiRISEReferences edit a b c d e f g h i j k l Sullivan R et al 2001 Mass Movement Slope Streaks Imaged by the Mars Orbiter Camera J Geophys Res 106 E10 23 607 23 633 a b c d Chuang F C Beyer R A Bridges N T 2010 Modification of Martian Slope Streaks by Eolian Processes Icarus 205 154 164 a b Schorghofer N Aharonson O Khatiwala S 2002 Slope Streaks on Mars Correlations with Surface Properties and the Potential Role of Water Geophys Res Lett 29 23 2126 doi 10 1029 2002GL015889 Morris E C 1982 Aureole Deposits of the Martian Volcano Olympus Mons J Geophys Res 87 B2 1164 1178 a b c d Ferguson H M Lucchitta B K 1984 Dark Streaks on Talus Slopes Mars in Reports of the Planetary Geology Program 1983 NASA Tech Memo TM 86246 pp 188 190 https ntrs nasa gov archive nasa casi ntrs nasa gov 19840015363 1984015363 pdf a b c d e f g Chuang F C et al 2007 HiRISE Observations of Slope Streaks on Mars Geophys Res Lett 34 L20204 doi 10 1029 2007GL031111 Sullivan R Daubar I Fenton L Malin M Veverka J 1999 Mass Movement Considerations for Dark Slope Streaks Imaged by the Mars Orbiter Camera 30th Lunar and Planetary Science Conference Abstract 1809 http www lpi usra edu meetings LPSC99 pdf 1809 pdf Barlow 2008 p 141 a b Read Publish Review AGU Retrieved 2022 09 30 Webster Guy Brown Dwayne December 10 2013 NASA Mars Spacecraft Reveals a More Dynamic Red Planet NASA Retrieved December 10 2013 a b c Kreslavsky M A Head J W 2009 Slope Streaks on Mars A New Wet Mechanism Icarus 201 517 527 a b c d e Aharonson O Schorghofer N Gerstell M F 2003 Slope Streak Formation and Dust Deposition Rates on Mars J Geophys Res 108 E12 5138 doi 10 1029 2003JE002123 Dundas C 2018 HIRISE OBSERVATIONS OF NEW MARTIAN SLOPE STREAKS 49th Lunar and Planetary Science Conference 2018 LPI Contrib No 2083 2026 pdf Junior C and T Statella 2023 Monitoring martian slope streaks in the northeast of Lysus sulci Icarus 406 115737 Bhardwaj A et al 2018 Are Slope Streaks Indicative of Global Scale Aqueous Processes on Contemporary Mars Reviews of Geophysics Volume 57 Issue 1 p 48 77 a b c d Baratoux D et al 2006 The Role of the Wind Transported Dust in Slope Streaks Activity Evidence from the HRSC Data Icarus 183 30 45 Barlow 2008 p 73 Hartmann 2003 pp 36 41 a b c Schorghofer Aharonson O Gerstell M F Tatsumi L 2007 Three Decades of Slope Streak Activity on Mars Icarus 191 132 140 doi 10 1016 j icarus 2007 04 026 a b Malin M C Edgett K S 2001 Mars Global Surveyor Mars Orbiter Camera Interplanetary cruise through primary mission J Geophys Res 106 E10 23 429 23 570 a b Williams S H 1991 Dark Talus Streaks on Mars are Similar to Aeolian Dark Streaks 22nd Lunar and Planetary Science Conference Abstract 1750 http www lpi usra edu meetings lpsc1991 pdf 1750 pdf Catalog Page for PIA22240 photojournal jpl nasa gov Retrieved 2 April 2018 Phillips C B Burr D M Beyer R A 2007 Mass Movement within a Slope Streak on Mars Geophys Res Lett 34 L21202 doi 10 1029 2007GL031577 Catalog Page for PIA09030 photojournal jpl nasa gov Retrieved 2022 09 30 Putzig N E et al 2005 Global Thermal Inertia and Surface Properties of Mars from the MGS Mapping Mission Icarus 173 325 341 Heavens N et al 2017 WIDESPREAD LOW LATITUDE DIURNAL CO2 FROST ON MARS Lunar and Planetary Science XLVIII 2017 1485pdf Treiman A H Louge M Y 2004 Martian Slope Streaks and Gullies Origins as Dry Granular Flows 35th Lunar and Planetary Science Conference Abstract 1323 http www lpi usra edu meetings lpsc2004 pdf 1323 pdf See Ferris et al 2002 for a discussion Jaret S J Clevy J R 2007 Distribution of Dark Slope Streaks in and Around Schiaparelli Impact Basin Mars 38th Lunar and Planetary Science Conference Abstract 1973 http www lpi usra edu meetings lpsc2007 pdf 1973 pdf Albin E F King J D 2001a Dark Slope Streaks and Associated Layered Deposits on the Southwestern Floor of Cassini Impact Basin Mars 32nd Lunar and Planetary Science Conference Abstract 1380 http www lpi usra edu meetings lpsc2001 pdf 1380 pdf Albin E F King J D 2001b Origin of Dark Slope Streaks Within the Schiaparelli Impact Basin Mars 32nd Lunar and Planetary Science Conference Abstract 1395 http www lpi usra edu meetings lpsc2001 pdf 1395 pdf http www uahirise org epo nuggets dust avalanche pdf bare URL PDF HiRISE Bang and Whoosh ESP 054066 1920 Kaylan J Burleigh Henry J Melosh Livio L Tornabene Boris Ivanov Alfred S McEwen Ingrid J Daubar Impact air blast triggers dust avalanches on Mars Icarus 2012 217 1 194 doi 10 1016 j icarus 2011 10 026 Red Planet Report What s new with Mars redplanet asu edu Retrieved 2 April 2018 Meteorite shockwaves trigger dust avalanches on Mars phys org Retrieved 2 April 2018 https www sciencedirect com wikipedialibrary idm oclc org science article pii S0019103520303249 bb0020 Heyer T et al 2020 Dust devil triggering of slope streaks on Mars Icarus Icarus Volume 351 113951 Edgett K S Malin M C Sullivan R J Thomas P Veverka J 2000 Dynamic Mars New Dark Slope Streaks Observed on Annual and Decadal Time Scales 31st Lunar and Planetary Science Conference Abstract 1058 http www lpi usra edu meetings lpsc2000 pdf 1058 pdf Bergonio J K Rottas and N Schorghofer 2013 Properties of martian slope streak populations Icarus 225 194 199 Gerstell M F Aharonson O Schorghofer N 2004 A Distinct Class of Avalanche Scars on Mars Icarus 168 122 130 a b c McEwen Alfred S Ojha Lujendra Dundas Colin M Mattson Sarah S Byrne Shane Wray James J Cull Selby C Murchie Scott L Thomas Nicolas Gulick Virginia C 2011 08 05 Seasonal Flows on Warm Martian Slopes Science 333 6043 740 743 Bibcode 2011Sci 333 740M doi 10 1126 science 1204816 ISSN 0036 8075 PMID 21817049 S2CID 10460581 a b Mann Adam 18 February 2014 Strange Dark Streaks on Mars Get More and More Mysterious Wired Retrieved 18 February 2014 Chang Kenneth 2011 08 04 Scientists Find Signs Water Is Flowing on Mars The New York Times ISSN 0362 4331 Retrieved 2022 09 30 HiRISE Science in Motion Seasonal Flows on Warm Martian Slopes hirise lpl arizona edu Retrieved 2022 09 30 McEwen A Ojha L Dundas C Mattson S Byrne S Wray J Cull S Murchie S 2011 Transient Slope Lineae Evidence for Summertime Briny Flows on Mars 42nd Lunar and Planetary Science Conference Abstract 2314 http www lpi usra edu meetings lpsc2011 pdf 2314 pdf Schorghofer N King C M 2011 Sporadic Formation of Slope Streaks on Mars Icarus 216 1 159 168 a b Levy J S Fountain A G 2011 Water Tracks in the McMurdo Dry Valleys Antarctica A Permafrost Based Hydrological System Supporting Complex Biological and Geochemical Processes in a Mars Analog Environment 42nd Lunar and Planetary Science Conference Abstract 1210 http www lpi usra edu meetings lpsc2011 pdf 1210 pdf Further reading editBarlow N G 2008 Mars An Introduction to Its Interior Surface and Atmosphere Cambridge University Press Cambridge UK ISBN 978 0 521 85226 5 Hartmann William K 2003 A Traveler s Guide to Mars The Mysterious Landscapes of the Red Planet Workman New York ISBN 0 7611 2606 6 Portal nbsp Solar System Retrieved from https en wikipedia org w index php title Dark slope streak amp oldid 1184678044, wikipedia, wiki, book, books, library,

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