झरना भूविज्ञान

झरना, क्षेत्र जहां बहती नदी का पानी अचानक गिरता है और लगभग लंबवत (वीडियो देखें)। झरने नदी के प्रवाह में प्रमुख रुकावटों का प्रतिनिधित्व करते हैं। अधिकांश परिस्थितियों में, नदियाँ कटाव और निक्षेपण की प्रक्रियाओं द्वारा उनके प्रवाह में अनियमितताओं को सुचारू करती हैं। समय में, एक नदी की लंबी प्रोफ़ाइल (इसकी ढाल का ग्राफ) एक चिकनी वक्र का रूप लेती है, स्रोत की ओर सबसे तेज, मुंह की ओर जेंटलेस्ट। झरने इस वक्र को बाधित करते हैं, और उनकी उपस्थिति क्षरण की प्रगति का एक उपाय है। जलप्रपात को कभी-कभी गिरना या मोतियाबिंद भी कहा जा सकता है, बाद वाला पदनाम सबसे आम है जब पानी की बड़ी मात्रा शामिल होती है। छोटी ऊँचाई और कम ऊँचाई वाले झरनों को झरना कहा जाता है; यह शब्द अक्सर एक नदी के किनारे छोटे-छोटे झरनों की श्रृंखला पर लागू होता है।फिर भी जेंटलर उन नदियों तक पहुंचता है, जो चैनल ढाल में स्थानीय वृद्धि के जवाब में अशांत प्रवाह और सफेद पानी दिखाती हैं, रैपिड कहलाती हैं।

नदी: झरने

झरना, जिसे कभी-कभी मोतियाबिंद कहा जाता है, एक नदी चैनल के अचानक खड़ी होने से उत्पन्न होता है जो पानी के प्रवाह का कारण बनता है

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झरने का एक संक्षिप्त उपचार निम्नानुसार है। पूर्ण उपचार के लिए, नदी देखें: झरने।

दुनिया का सबसे ऊंचा झरना वेनेजुएला में एंजेल जलप्रपात (807 मीटर [2,650 फीट]) है। संभवतः लाओस में मेकांग नदी पर सबसे बड़ा झरना च्यूट डी कोन (कोन फॉल्स) है: इसके ऊपर से गुजरने वाले पानी की मात्रा 11,600 क्यूबिक मीटर (410,000 क्यूबिक फीट) प्रति सेकंड आंकी गई है, हालांकि इसकी ऊंचाई केवल 70 मीटर है (230 फीट) है।

There are several conditions that give rise to waterfalls. One of the most common reasons for a waterfall’s existence is difference in rock type. Rivers cross many lithological boundaries, and, if a river passes from a resistant rock bed to a softer one, it is likely to erode the soft rock more quickly and steepen its gradient at the junction between the rock types. This situation can occur as a river cuts and exhumes a junction between different rock beds. The riverbed of Niagara Falls, which forms part of the boundary between the United States and Canada, has a blocky dolomite cap overlying a series of weaker shales and sandstones.

A related cause of waterfalls is the presence of bars of hard rock in the riverbed. A series of cataracts has been created on the Nile where the river has worn its bed sufficiently to uncover the hard crystalline basement rock.

Other waterfalls are caused less by the character of rock formations and more by the structure or shape of the land. Uplifted plateau basalts, for example, may provide a resistant platform at the edge of which rivers produce waterfalls, as occurs on the Antrim basalts in Northern Ireland. On a much larger scale, the morphology of the southern half of Africa, a high plateau surrounded by a steep scarp slope, creates waterfalls and rapids on most of the area’s major rivers. These include the Livingstone Falls on the Congo River and the Augrabies Falls on the Orange River. In general, the occurrence of waterfalls increases in mountainous terrain as slopes get steeper.

Erosion and geology are not the only factors that create waterfalls. Tectonic movement along a fault may bring hard and soft rocks together and encourage the establishment of a waterfall. A drop in sea level promotes increased downcutting and the retreat upstream of a knickpoint (sharp change of gradient indicating the change of a river’s base-level). Depending on the change of sea level, river flow, and geology (among other factors), falls or rapids may develop at the knickpoint. Many waterfalls have been created by glaciation where valleys have been over-deepened by ice and tributary valleys have been left high up on steep valley sides. In the glacially gouged Yosemite Valley in California, the Yosemite Upper Falls tumble 436 m (1,430 feet) from such a hanging valley.

Within a river’s time scale, a waterfall is a temporary feature that is eventually worn away. The rapidity of erosion depends on the height of a given waterfall, its volume of flow, the type and structure of rocks involved, and other factors. In some cases the site of the waterfall migrates upstream by headward erosion of the cliff or scarp, while in others erosion may tend to act downward, to bevel the entire reach of the river containing the falls. With the passage of time, by either or both of these means, the inescapable tendency of rivers is to eliminate any waterfall that may have formed. The energy of rivers is directed toward the achievement of a relatively smooth, concave upward, longitudinal profile.

Even in the absence of entrained rock debris, which serve as an erosive tool of rivers, the energy available for erosion at the base of a waterfall is great. One of the characteristic features associated with waterfalls of any great magnitude, with respect to volume of flow as well as to height, is the presence of a plunge pool, a basin that is scoured out of the river channel beneath the falling water. In some instances the depth of a plunge pool may nearly equal the height of the cliff causing the falls. Plunge pools eventually cause the collapse of the cliff face and the retreat of the waterfall. Retreat of waterfalls is a pronounced feature in some places. At Niagara, for example, the falls have retreated 11 km (7 miles) from the face of the escarpment where they began. Today much of Niagara’s water is diverted for hydroelectric power generation, but it has been estimated that with normal flow the rate of retreat would be about 1 m (3 feet) per year.