1 / 21

Soils on Slopes – Summary:

Soils on Slopes – Summary: A soil on a slope has strength because of inherent frictional properties, cohesion and normal load (pushing into slope). Shear stress acts on the soil because of the downslope component of gravity and the weight of the soil (pushing downslope).

eldora
Download Presentation

Soils on Slopes – Summary:

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Soils on Slopes – Summary: A soil on a slope has strength because of inherent frictional properties, cohesion and normal load (pushing into slope). Shear stress acts on the soil because of the downslope component of gravity and the weight of the soil (pushing downslope). These properties can be measured and strength and stress can be quantified in mathematical equations. If stress exceeds strength, slope failure results; this is often triggered by a change in conditions e.g. heavy rain. Harry Williams, Geomorphology

  2. I-35W about 1 mile south of Denton Harry Williams, Geomorphology

  3. Harry Williams, Geomorphology

  4. Harry Williams, Geomorphology

  5. Harry Williams, Geomorphology

  6. Harry Williams, Geomorphology

  7. ROCK AND SOIL STRENGTH II.Rock strength can be dependent on many different factors. A scheme devised by geomorphologist M.J. Selby incorporates 7 factors: 1. Strength of intact rock 2. Degree of weathering 3. Joint Spacing 4. Joint orientation 5. Joint width 6. Joint continuity and infill 7. Flow of ground water through joints Selby’s approach allows QUANTIFICATION of these factors so that the strength of a rock can be measured. Harry Williams, Geomorphology

  8. DIFFERENTIAL EROSION CREATES LANDFORMS Harry Williams, Geomorphology

  9. 1. Strength of intact rock (20%) - depends mainly on mineral composition and rock structure. Granite, for example, is mainly hard feldspar and quartz grains which interlock, making for a strong rock. Microscopic view showing interlocking crystals. Harry Williams, Geomorphology

  10. Flaking of shale shale Shale is mainly soft clay minerals with a platey structure which flakes easily -> relatively soft. Note: General rule of thumb: igneous and metamorphic rock = fairly hard; clastic sedimentary rock = fairly soft; limestone varies e.g. chalk = soft, other types of limestone can be quite hard. Harry Williams, Geomorphology

  11. 2. State of weathering (10%) Weathering changes hard minerals into softer ones and loosens up the structure of a rock -> reduced strength (note: complete weathering creates soil). This means that even a hard rock like granite can be a lot softer if it’s highly weathered. Harry Williams, Geomorphology

  12. 3. Joint spacing (30%) - all cohesive strength is lost along a joint - the greater the density of joints, the weaker the rock (close spacing results in a greater number of joints). hills mountains Devil’s Post Pile, California. Highly jointed basalt - the result is a weak erodible rock, as seen by the pile of debris at the base of the cliff. cliffs ridges Harry Williams, Geomorphology

  13. 4. orientation of joints (20%) - dip into slope = stronger; dip out of slope = weaker; can be graded accordingly. valleys stronger canyons dip deltas dip weaker beaches Harry Williams, Geomorphology

  14. 5. Width of joints (7%) - affects cohesion, friction and water movement - the wider the joints the weaker the rock. 6. Continuity of joints and amount of joint infill with soil (7%) - Thick infill -> weaker rock, because strength of rock becomes strength of infilling soil (i.e. no points of rock contact along joint plane - all shear stress carried by weak soil layer in the joint). Harry Williams, Geomorphology

  15. 7. Ground water outflow (6%) - as in soil, water can develop positive pressure in joints in rock. This water pressure can push rocks apart, effectively lowering friction and decreasing strength. The water pressure can be estimated based on outflow of water from the rock (table 6.2). Harry Williams, Geomorphology

  16. Big Hill Seep, Carlsbad Caverns, NM. Harry Williams, Geomorphology

  17. Harry Williams, Geomorphology

  18. Main Points 1. Joint characteristics can account for up to 70% of rock strength - a highly jointed granite can be less resistant to erosion than a compact unjointed sandstone. 2. In the absence of joints, the initial rock strength and the state of weathering become most important. Rockfalls of large blocks of Austin Chalk detached along joints. Harry Williams, Geomorphology

  19. Example rock slope from Antarctica: alternating beds of dolerite (a hard volcanic rock) and various types of sandstone (some hard, some soft). Woodbine sandstone Harry Williams, Geomorphology

  20. Measurement of rock mass strength (Table 6.2) and slope angle. depositional Harry Williams, Geomorphology

  21. Harry Williams, Geomorphology

More Related