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== Hydrological indicators ==
== Hydrological indicators ==
A perennial stream can be identified 48 hours after a storm, if a stream is still flowing and there is no visible determination of flow above the channel then it is a good indicator that base flow is occurring in the stream. Another perennial stream identifier is when there is an abundance of red rust material, in a slow moving wetted channel or stagnant area, which are iron oxidizing bacteria that form when oxygen depleted ground water is exposed to the surface. Looking for leaf litter is an additional indicator when trying to access if a stream is perennial. Perennial streams should have no accumulation of leaf litter in the bed due to continuous transport of plant material through the channel. In addition nearby plants, in an active flood plain of a perennial streams, will have fine sediment deposited on plants. Also, an organic drift line composed of organic debris in piles or lines will be present on the active floodplain indicating recent high flows.<ref name=":0" />
A perennial stream can be identified 48 hours after a storm. Direct storm runoff usually has ceased at this point. If a stream is still flowing and contributing inflow is not observed above the channel, the observed water is likely baseflow. Another perennial stream indication is an abundance of red rust material in a slow-moving wetted channel or stagnant area. This is evidence that [[iron-oxidizing bacteria]] are present, indicating persistent expression of oxygen-depleted ground water. In a forested area, leaf and needle litter in the stream channel is an additional indicator. Accumulation of leaf litter does not occur in perennial streams since such material is continuously flushed. In the adjacent overbank of a perennial stream, fine sediment may cling to riparian plant stems and tree trunks. Organic debris drift lines or piles may be found within the active overbank area after recent high flow.<ref name=":0" />


==See also==
==See also==

Revision as of 15:53, 16 June 2020

Whites Creek a small perennial stream in the Ozarks of southern Missouri

A perennial stream or perennial river is a stream or river (channel) which has constant stream throughout the year through parts of its stream bed during years of normal rainfall.[1] In the absence of irregular, prolonged, or extreme drought, a perennial stream is a watercourse, or segment, element, or emerging body of water which continually delivers groundwater. For example, an artificial disruption of stream, variability in flow or stream selection associated with the activity in hydropower installations, shall not affect the measurement. Perennial streams do not consist of stagnant water for the wetlands, reservoirs, and ponds that occur all the period. All other streams, or portions thereof, should be considered seasonal rivers or lakes. The stream can cycle from broken to perpetual through multiple iterations, to intermittent through its mechanism. [2][3]

Stream

Definition

The basic concept means flowing bodies of water. In hydrology, the "lake" usually refers to water flowing through natural passages separated from canals. More broadly it refers to move in any pipe, natural or artificial water, in the term drooling.

The flow is the main component of water and the drainage of surface water through the bed of the river and the bank of the river. The flows are regulated by 3 aspects. -- Surface water, subsurface water, and the water underneath the ground. During the rainy seasons, surface and subsurface water differed greatly. Groundwater is reasonably stable and regulated by trends of long-term precipitation.The patterns include surface, subsurface, and groundwater. And these factors flow into geological, geomorphological, hydrological, and biological controls.[1]

Depending on where the flow locates on or on characteristic and special characteristics or traits of the stream, different local or regional names that call the name of the stream. The large-scale rivers are generally called dams.

Generally speaking, surface hydrology is an essential part of research into water flow and watercourse, and is the central part of the geography of the world.

Classification

The following can be listed as streams in natural channels :

According to the time:

  • Perennial: The one which flows continuously.
  • Intermittent or seasonal: it occurs only in a certain time of the year when it receives ample water from springs or other ground source in mountainous areas, such as mountain snow melting.
  • Ephemeral: One that only flows in direct reaction to rainfall, and whose channel is always at the top of the water table.

According to space:

  • Continuous: One which has no spatial interruptions.
  • Interrupted: The one with alternative arrivals. They are sporadic, permanent, or low.

According to the water underneath:

  • Gaining: A stream or path to receive water from polluted belts.
  • Losing: A stream or reach of a stream giving the saturation zone plenty of water.
  • Isolated: The water flow or channel shall not supply or remove water from the saturated region. It does not have separate permeability bed from the wet area.
  • Perched: The sedimentation flow refers to the loss or isolation flow separated from the groundwater in the air zone.Classification[4]

Importance

The importance of Streams: Streams, headwaters, and streams flowing only part of the year provide many benefits upstream and downstream. They defend against floods, remove contaminants, recycle nutrients that are potentially dangerous as well as provide food and habitat for many forms of fish. Such streams also play a vital role in preserving our drinking water quality and supply, ensuring a steady flow of water to surface waters and helping to restore deep aquifers. 1.Clean Drinking Water 2.Flood and erosion protection 3.Groundwater recharge 4.Pollution reduction 5.Wildlife habitat 6.Economic importance in fishing, hunting, manufacting and agriculture.[5]

Etymology

The word "perennial" from the 1640s, meaning "evergreen," is established in Latin perennis, keeping the meaning as "everlasting all year round," per "over" plus annus "year." This has been proved since the 1670s by the "living years" in the sense of botany. The metaphorical sense of "enduring, eternal" originates from 1750. They are related to "Perennial." See Biennial for shifts in vowels.The term means "perennial" and was in 1763. [6]

Difference between Perennial stream and intermittent stream

How to tell the difference between a perennial stream and an intermittent stream?

Characteristics

Perennial streams have one or more of these characteristics:

  1. Direct observation or compelling evidence suggests that there is no interruption in the flow at ground.
  2. The existence of one or more specific features of the perennial streams, including:
    • Riverbed forms, for example, riffles, pools, runs, gravel bars, other depositional characteristics, bed armor layer.
    • Riverbank erosion and/or polishment.
    • Indications of waterborne debris and sediment transport.
    • Defined river or stream bed and banks.
  3. The catchment area exceeds .25 square miles (0.65 km2).
  4. USGS regression on the VHD data layer-oriented[definition needed] application on the probability of intermittent flow.
  5. The existence of aquatic organisms that require uninterrupted circulation.
  6. As shown by bank leakage, spring, or other indicators, grass-roots flow mainly supports groundwater recharge.
  7. There are high channels of permeability, especially stratospheric, boundary conditions; while stratospheric groundwater also decreases on occasion.
  8. Existence of native aquatic organisms which require undisturbed survival flow.
  9. The surrounding topography exhibits features of being formed by fluvial processes.

Absence of such characteristics supports classifying a stream as intermittent, "showing interruptions in time or space".[7]

Sources

The streams typically derive most of their water from rain and snow precipitation. Most of this water re-enters the atmosphere either by evaporating from soil and water bodies, or by plant evapotranspiration. By infiltration some of the water sinks into the earth and becomes groundwater, much of which eventually enters streams. Most precipitated water is partially bottled up by evaporation or freezing in snow fields and glaciers. The majority of the water flows as a runoff off the ground, the proportion of which varies depending on several factors, such as climate, temperature, vegetation, types of rock, and relief. This runoff begins as a thin layer called sheet wash, combined with a network of tiny rills, which together form the sheet runoff; when this water is focused in a channel, a stream is born. Some rivers and streams may begin from lakes or ponds.

Freshwater's primary sources are precipitation, and mountain snowmelt. However, rivers typically originate in the highlands, and are slowly created by the erosion of mountain snowmelt into lakes or rivers. Rivers usually flow from their source topographically, and erode as they pass until they reach the base stage of erosion.

The scientists have offered a way based on data to define the origin of the lake. A classified sample was the one measured by the Chinese researchers from the University of Chinese Academy of Sciences.

As an essential symbol of the river formation environment, the river source needs an objective and straightforward and effective method of judging. A calculation model of river source catchment area based on critical support flow (CSD) proposed, and the relationship between CSA and CSD with a minimum catchment area established. Using the model for comparison in two basins in Tibet (Helongqu and Niyang River White Water) in Tibet, the results show that the critical support flow (Qc) of the housing dragon song[clarification needed] is 0.002 8 m3/s. At the same time, the white water curvature is 0.008 5 m3/s. Besides, the critical support flow can vary with hydrologic climate conditions, and the vital support flow Qc in wet areas (white water) is larger than in semi-arid regions (heap slot). The proposed critical support flow (CSD) concept and model method can be used to determine the hydrographic indicators of river sources in complex geographical areas, and it can also reflect the impact of hydrologic climate change on river recharge in different regions.[8]

The river's source is the river's point of origin. It can consist of lakes, swamps, springs, or glaciers. It is here that the stream starts. A typical river consists of several tributaries, and each arm may be made up of several other smaller tributaries, so that together this stream and all its tributaries are called a drainage network. Although the current and each branch has its source, international practice is to take the source farthest from the end as the source of the entire river system, from which the most extended length of the river measured as the starting point is taken as the length of the whole river system.[9]

Generally speaking, the source of a river system will be at the beginning of the current or its upper reaches, where the river length is synonymous with the size of the river system unless otherwise specified. For example, the origin of the Nile River is the confluence of the White Nile and the Blue Nile, and the source of the whole river system is in its upper reaches. If there is no specific designation, "Nile length" refers to "river length of the Nile system," rather than to the length of the Nile river.The Nile's source is often known as Lake Victoria, but the lake has significant feeder rivers. The Kagera River, which flows into Lake Victoria near Bukoba's Tanzanian town, is the longest feeder, though sources do not cooperate on which is the Kagera 's longest tributary and therefore the Nile's most remote source itself.[10] [11]

Benthic macroinvertebrates

Macroinvertebrate refer to easily seen invertebrates, larger than 0.5 mm and can be collected from stream and river bottoms.[12] The larval stages of most aquatic insects are good indicators of perennial streams. Larva such as caddisflies, mayflies, stoneflies, and damselflies[13] require a continuous aquatic habitat until they reach maturity. Crayfish and other crustaceans plus snails and aquatic worms also indicate a good chance that the stream being assessed is perennial. Another great indicator of a perennial stream would be the presence of a clams. Bivalves (clams) require a persistent aquatic environment for survival.[14]

Vertebrates

Fish and amphibians are secondary indicators when it comes to assessing for a perennial stream because some fish and amphibians can inhabit areas without persistent water regime. When assessing for fish, all available habitat should be assessed; from pools, riffles, root clumps and other obstructions. Fish will seek cover if alerted to human presence but should be easily observed in perennial streams. Amphibians also indicate a perennial stream and range from tadpoles, frogs, salamanders, and newts. These amphibians can be found in stream channels, along streambanks, and even under rocks. Frogs and tadpoles usually inhabit shallow and slow moving waters near the sides of stream banks. Frogs will typically jump into water when alerted to human presence.[14]

Geological indicators

Well defined river beds composed of riffles, pools, runs, gravel bars, a bed armor layer, and other depositional features, plus well defined banks due to bank erosion are good identifiers when assessing for perennial streams.[15] Particle size will help identify a perennial stream. Perennial streams cut through the soil profile which removes fine and small particles. By assessing areas for relatively coarse material left behind in the stream bed and finer sediments along the side of the stream or within the floodplain will be a good indicator of persistent water regime.[13]

Hydrological indicators

A perennial stream can be identified 48 hours after a storm. Direct storm runoff usually has ceased at this point. If a stream is still flowing and contributing inflow is not observed above the channel, the observed water is likely baseflow. Another perennial stream indication is an abundance of red rust material in a slow-moving wetted channel or stagnant area. This is evidence that iron-oxidizing bacteria are present, indicating persistent expression of oxygen-depleted ground water. In a forested area, leaf and needle litter in the stream channel is an additional indicator. Accumulation of leaf litter does not occur in perennial streams since such material is continuously flushed. In the adjacent overbank of a perennial stream, fine sediment may cling to riparian plant stems and tree trunks. Organic debris drift lines or piles may be found within the active overbank area after recent high flow.[13]

See also

References

  1. ^ a b Meinzer, Oscar E. (1923). Outline of ground-water hydrology, with definitions. Washington, DC: US Geological Survey (USGS). p. 57. {{cite book}}: Cite has empty unknown parameter: |coauthors= (help) Water Supply Paper 494.
  2. ^ Technical Guidance for Identification of Perennial Stream For the Purpose of Jurisdictional Determinations Under 10 VSA Section 1021(a) and 1002(10) (PDF). 2018. Definition of Perennial Stream
  3. ^ "Temporary vs. Perennial Streams". Michael Arthur and Demian Saffer Professors, The Pennsylvania State University - University Park, Patrick Belmont Assistant Professor, Utah State University.
  4. ^ Langbein, W.B.; Iseri, Kathleen T. (1995). "Hydrologic Definitions: Stream". Manual of Hydrology: Part 1. General Surface-Water Techniques (Water Supply Paper 1541-A). Reston, VA: USGS. Archived from the original on 2012-05-09.
  5. ^ "The importance of stream". United States Enviornmental Protection Agency.
  6. ^ "perennial stream | Search Online Etymology Dictionary". www.etymonline.com. Retrieved 2018-05-08.
  7. ^ Technical Guidance for Identification of Perennial Stream For the Purpose of Jurisdictional Determinations Under 10 VSA Section 1021(a) and 1002(10) (PDF). 2018. Characteristic of perennial stream
  8. ^ "Developments in Water Science | Book series | ScienceDirect.com". www.sciencedirect.com.
  9. ^ "基于临界支撑流量的西藏典型河流源头位置确定及河网解析研究-四川大学学报(工程科学版)2014年06期-手机知网" [The Determination of the Source of the Typical River in Tibet Based on the Critical Support Flow and the Analysis of the River Network Analysis-Journal of Sichuan University (Engineering Science Edition) 2014-06-Find dissertations and theses]. wap.cnki.net.
  10. ^ McLeay, Cam (2 July 2006). "The Truth About the Source of R. Nile". New Vision. Archived from the original on 9 April 2011. Retrieved 31 August 2011.
  11. ^ Malone, Barry. "Next on Egypt's to-do: Ethiopia and the Nile". www.aljazeera.com. Archived from the original on December 9, 2013.
  12. ^ "A Citizen's Primer on Stream Ecology, Water Quality, Hydrology, and Fluvial Geomorphology-Volume II" (PDF).
  13. ^ a b c "Methodology for Identification of Intermittent and Perennial Streams and Their Origins" (PDF).[dead link]
  14. ^ a b "Perennial Stream Field Identification Protocol May 2003" (PDF). www.deq.virginia.gov.[dead link]
  15. ^ "Technical guidance for Identification of Perennial Stream For the Purpose of Jurisdictional Determinations Under 10 VSA Section 1021(a) and 1002(10) January 16, 2018" (PDF).

More references:

  1. Nile Basin Initiative. 2011. Archived from the original on 2 September 2010. Retrieved 1 February 2011.
  2. Telegraph. Archived from the original on 3 May 2012. Retrieved 6 September 2012. Journey to the source of the Nile.
  3. Cheng Haining, Liu Shaoyuan. Discussion on criteria for the determination of sources of large rivers [J]. Qinghai Land Survey 2009, 06:24-28.
  4. Li, Zhouyuan; Liu, Xuehua; Niu, Tianlin; Kejia, De; Zhou, Qingping; et al. Environmental science & technology Vol. 49, Iss. 10,  (May 19, 2015): 5897-5904. DOI:10.1021/es505985q
  5. "A Citizen's Primer on Stream Ecology, Water Quality, Hydrology, and Fluvial Geomorphology-Volume II" (PDF).