Scree - Related Links
Open Access Articles- Top Results for Scree
International Journal of Innovative Research in Science, Engineering and TechnologyHydro Carbon Gas Detection Based On Zeolite Gas Sensor Device
Journal of Community Medicine & Health EducationA Prospective Study to Assess the Quality of Preliminary Eye Screening Done on School Children by Teachers in Andhra Pradesh
Journal of Diabetes & MetabolismAudit of Screening for Diabetic Nephropathy in a Teaching Hospital in Nigeria
Journal of Stem Cell Research & TherapyAnti-Cancer Drug Screening Based on a Adipose-Derived Stem Cell/Hepatocyte 3D Printing Technique
International Journal of Innovative Research in Computer and Communication EngineeringA Method of Segmentation For Glaucoma Screening Using Superpixel Classification
Scree is a collection of broken rock fragments at the base of crags, mountain cliffs, volcanoes or valley shoulders that has accumulated through periodic rockfall from adjacent cliff faces. Landforms associated with these materials are often called talus deposits. Talus deposits typically have a concave upwards form, while the maximum inclination corresponds to the angle of repose of the mean debris size.
Formation of scree or talus deposits results from physical and chemical weathering and erosional processes acting on a rock face. The predominant processes that degrade a rock slope depend largely on the regional climate (temperature, amount of rainfall, etc.). Examples include:
- Mechanical weathering by ice
- Chemical weathering by mineral hydration and salt deposition
- Thermal stresses
- Topographic stresses
- Biotic processes
Scree formation is commonly attributed to the formation of ice within mountain rock slopes. During the day, water can flow in joints and discontinuities in the rock wall. If the temperature drops sufficiently, for example with the onset of evening, this water may freeze. Since water expands by 9% when it freezes, it can generate large forces that either creates new cracks or wedges blocks into an unstable position. Special boundary conditions (rapid freezing and water confinement) may be required for this process to be effective. Freeze-thaw scree production is thought to be most common during the spring and fall, when the daily temperatures fluctuate around the freezing point of water, and snow melt produces ample free water.
The efficiency of freeze/thaw processes in scree production is the subject of some debate in the scientific community. Many researchers believe that it is unrealistic to assume that ice formation in large open crack systems can generate large pressures, instead suggesting that the water and ice simply flow out of the cracks as pressure builds. Many argue that a frost heaving process, like that known to act in soil in permafrost areas, may in fact play an important role in cliff degradation in cold environments.
Scree can conceal a glacier. For example, Lech dl Dragon, in the Sella Group of the Dolomites, derives from the melting waters of a glacier, hidden under a thick layer of scree. The melting process of the underlying glacier is slowed by the protective layer of scree.
With sufficient time, a rock slope may become completely covered by its own scree so that production of new material ceases. This slope is said to be mantled with debris.
|40x40px||Wikimedia Commons has media related to Screes.|
|40x40px||Look up scree or talus in Wiktionary, the free dictionary.|
- Harper, Douglas. "scree". Online Etymology Dictionary. Retrieved 2006-04-20.
- Harper, Douglas. "talus". Online Etymology Dictionary. Retrieved 2008-12-01.
- "Talus". bab.la language portal. Retrieved 2011-12-10.
- Whalley, WB (1984). "Rockfalls". In Brunsden, D.; Prior, DB. Slope Instability. Chichester: John Wiley and Sons. pp. 217–256.
- Hallet, B (2006). "Why do freezing rocks break?". Science 314 (5802): 1092–1093. PMID 17110559. doi:10.1126/science.1135200.
- Walder, J; Hallet, B (1985). "A theoretical model of the fracture of rock during freezing". Geological Society of America Bulletin 96 (3): 336–346. Bibcode:1985GSAB...96..336W. doi:10.1130/0016-7606(1985)96<336:ATMOTF>2.0.CO;2.
- Murton, JB; Peterson, R; Ozouf, J-C (2006). "Bedrock fracture by ice segregation in cold regions". Science 314 (5802): 1127–1129. Bibcode:2006Sci...314.1127M. PMID 17110573. doi:10.1126/science.1132127.