Livio L. Tornabene Nina L. Lanza Chris H. Okubo 2011 <p><span>The value of&nbsp;slope stability&nbsp;analyses for gaining insight into the geologic conditions that would facilitate the growth of gully alcoves on Mars is demonstrated in Gasa&nbsp;crater. Two-dimensional limit&nbsp;equilibrium methods&nbsp;are used in conjunction with&nbsp;high-resolution topography derived from stereo High Resolution Imaging Science Experiment (HiRISE) imagery. These analyses reveal three conditions that may produce observed alcove morphologies through&nbsp;slope failure: (1) a&nbsp;</span><i>ca.</i><span>&nbsp;&gt;10</span><span>&nbsp;</span><span>m thick&nbsp;surface layer&nbsp;that is either saturated with H</span>₂<span>O ground ice or contains no groundwater/ice at all, above a zone of melting H</span>₂<span>O ice or groundwater and under dynamic loading (i.e., seismicity), (2) a 1–10</span><span>&nbsp;</span><span>m thick surface layer that is saturated with either melting H</span>₂<span>O ice or groundwater and under dynamic loading, or (3) a &gt;100</span><span>&nbsp;</span><span>m thick surface layer that is saturated with either melting H</span>₂<span>O ice or groundwater and under&nbsp;static&nbsp;loading. This finding of three plausible scenarios for slope failure demonstrates how the triggering mechanisms and characteristics of future alcove growth would be affected by prevailing environmental conditions. HiRISE images also reveal&nbsp;normal faults&nbsp;and other fractures tangential to the crowns of some gully alcoves that are interpreted to be the result of slope instability, which may facilitate future slope movement. Stability analyses show that the most failure-prone slopes in this area are found in alcoves that are adjacent to crown fractures. Accordingly, crown fractures appear to be a useful indicator of those alcoves that should be monitored for future landslide activity.</span></p> application/pdf 10.1016/j.icarus.2010.09.025 en Elsevier Constraints on mechanisms for the growth of gully alcoves in Gasa crater, Mars, from two-dimensional stability assessments of rock slopes article