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freshwater habitat with ecological classification of freshwater animals

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Mariyam Nazeer Agha

freshwater habitat, lentic and lotic systems

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BY: MARIYAM NAZEER AGHA KUD NO: 15S14233 DEPT. OF STUDIES IN ZOOLOGY GOVT. ARTS AND SCIENCE COLLEGE, KARWAR
 Introduction  Classification of freshwater ecosystem  Lentic ecosystem  Lentic system biota  Lotic ecosystem  Lotic system biota  Physical properties of freshwater  Chemical properties of freshwater  Biological properties of freshwater
 Freshwater ecosystems are a subset of Earth's aquatic ecosystems. They include lakes and ponds, rivers, streams, springs, and wetlands. They can be contrasted with marine ecosystems, which have a larger salt content.  Freshwater habitats can be classified by different factors, including temperature, light penetration, and vegetation.  Freshwater ecosystems are particularly vulnerable to the different components of climate change.  Freshwater ecosystems can be divided into lentic ecosystems (still water) and lotic ecosystems (flowing water).
 Lentic refers to stationary or relatively still water, from the Latin lentus, which means sluggish. Lentic waters range from ponds to lakes to wetlands, and much of this article applies to lentic ecosystems in general.  Lentic systems are diverse, ranging from a small, temporary rainwater pool a few inches deep to Lake Baikal, which has a maximum depth of 1740 m.  In addition, some lakes become seasonally stratified. Ponds and pools have two regions: the pelagic open water zone, and the benthic zone, which comprises the bottom and shore regions.  Since lakes have deep bottom regions not exposed to light, these systems have an additional zone, the profundal.  These three areas can have very different abiotic conditions and, hence, host species that are specifically adapted to live there.
 Bacteria  Bacteria are present in all regions of lentic waters. Free-living forms are associated with decomposing organic material, biofilm on the surfaces of rocks and plants, suspended in the water column, and in the sediments of the benthic and profundal zones.  Primary producers  Algae, including both phytoplankton and periphyton are the principle photosynthesizers in ponds and lakes.  Phytoplankton are found drifting in the water column of the pelagic zone.  Many species have a higher density than water which should make them sink and end up in the benthos.  To combat this, phytoplankton have developed density changing mechanisms, by forming vacuoles and gas vesicles or by changing their shapes to induce drag, slowing their descent.  Invertebrates  Zooplanktons are tiny animals suspended in the water column. Like phytoplankton, these species have developed mechanisms that keep them from sinking to deeper waters, including drag-inducing body forms and the active flicking of appendages such as antennae or spines.  Fish and other vertebrates  Fish have a range of physiological tolerances that are dependent upon which species they belong to.  They have different lethal temperatures, dissolved oxygen requirements, and spawning needs that are based on their activity levels and behaviors.  Because fish are highly mobile, they are able to deal with unsuitable abiotic factors in one zone by simply moving to another.
 Lotic refers to flowing water, from the Latin lotus, washed. Lotic waters range from springs only a few centimeters wide to major rivers kilometers in width.  The ecosystem of a river is the river viewed as a system operating in its natural environment, and includes biotic (living) interactions amongst plants, animals and micro-organisms, as well as abiotic (nonliving) physical and chemical interactions.  The following unifying characteristics make the ecology of running waters unique among aquatic habitats.  Flow is unidirectional.  There is a state of continuous physical change.  There is a high degree of spatial and temporal heterogeneity at all scales (microhabitats).  Variability between lotic systems is quite high.  The biota is specialized to live with flow conditions.
 Bacteria  Bacteria are present in large numbers in lotic waters. Free-living forms are associated with decomposing organic material, biofilm on the surfaces of rocks and vegetation, in between particles that compose the substrate, and suspended in the water column.  Primary producers  Algae, consisting of phytoplankton and periphyton, are the most significant sources of primary production in most streams and rivers.  Phytoplankton float freely in the water column and thus are unable to maintain populations in fast flowing streams. They can, however, develop sizable populations in slow moving rivers and backwaters.  Insects and other invertebrates  Up to 90% of invertebrates in some lotic systems are insects.  These species exhibit tremendous diversity and can be found occupying almost every available habitat, including the surfaces of stones, deep below the substratum, adrift in the current, and in the surface film.  Insects have developed several strategies for living in the diverse flows of lotic systems.  Fish and other vertebrates  Fish are probably the best-known inhabitants of lotic systems. The ability of a fish species to live in flowing waters depends upon the speed at which it can swim and the duration that its speed can be maintained.  This ability can vary greatly between species and is tied to the habitat in which it can survive.  Continuous swimming expends a tremendous amount of energy and, therefore, fishes spend only short periods in full current.
 Physical properties  Physical properties of aquatic ecosystems are determined by a combination of heat, currents, waves and other seasonal distributions of environmental conditions.  The morphometry of a body of water depends on the type of feature (such as a lake, river, stream, wetland, estuary etc.) and the structure of the earth surrounding the body of water. Lakes, for instance, are classified by their formation, and zones of lakes are defined by water depth.  Light interactions  Light zonation is the concept of how the amount of sunlight penetration into water influences the structure of a body of water. These zones define various levels of productivity within an aquatic ecosystems such as a lake. For instance, the depth of the water column which sunlight is able to penetrate and where most plant life is able to grow is known as the photic or euphotic zone. The rest of the water column which is deeper and does not receive sufficient amounts of sunlight for plant growth is known as the aphotic zone.  Thermal stratification  Similar to light zonation, thermal stratification or thermal zonation is a way of grouping parts of the water body within an aquatic system based on how each layer has different temperature variations. The less turbid the water, the more light is able to penetrate, and thus heating a thicker depth of water.  There are 3 main sections which define thermal stratification in a lake. The first is the epilimnion which is closest to the surface and experiences primarily wind circulation although the water is generally uniformally warm because of the close proximity to the surface.  The layer below is often called the thermocline and is an area within the water column which tends to experience a rapid decrease in temperature. Finally, the layer which is the bottom-most within the body of water is the hypolimnion which has uniformally cold water because of its depth which restricts sunlight from reaching it. In temperate lakes, fall-season cooling of surface water to 4 °C (the highest density of water) results in turnover of the water column.
The chemical composition of water in a natural environment is influenced mainly by precipitation, type of soil and bedrock in the watershed, erosion, evaporation and sedimentation. All bodies of water have a certain composition of both organic and inorganic elements and compounds.  Water quality  There are hundreds of variables which are considered to play a role in water quality however a few have been determined to be of greater interest regarding the role they play in aquatic ecosystem health. While certain biological activities affect dissolved gas concentrations, nutrients, etc. human activity is one of the strongest influences on water quality.  Oxygen  Dissolved oxygen is an element which is necessary for a number of biological and chemical reactions which are critical to the proper functioning of the ecosystem. Some of the biological processes which alter the concentrations of dissolved oxygen include photosynthesis and aquatic organism respiration. Oxygen profile is based on similar principles as thermal stratification and light penetration. Dissolved oxygen levels are generally lower as you move deeper into the body of water because of the lower availability of light in those parts of the water.  Carbon dioxide  Dissolve oxygen and dissolved carbon dioxide are often discussed together due the role they both play in aquatic organism respiration. These organisms absorb dissolved oxygen from the water to use in respiration and expel carbon dioxide as a byproduct of this process. Carbon dioxide tends to have an inverse diurnal relationship with oxygen.  Other nutrients  Nitrogen and phosphorus are ecologically significant nutrients in aquatic systems. Nitrogen is generally present as a gas in aquatic ecosystems Most of these dissolved nitrogen compounds follow a seasonal pattern with greater concentrations in the fall and winter months compared to the spring and summer. Phosphorus has a different role in aquatic ecosystems as it is a limiting factor in the growth of phytoplankton because of generally low concentrations in the water. Dissolved phosphorus is also crucial to all living things, is often very limiting to primary productivity in freshwater, and has its own distinctive ecosystem cycling.
 Lake trophic classification  Limnology (study of freshwater ecosystem), classifies lakes (or other bodies of water) according to the trophic state index.  An oligotrophic lake is characterised by relatively low levels of primary production and low levels of nutrients.  A eutrophic lake has high levels of primary productivity due to very high nutrient levels.  Eutrophication of a lake can lead to algal blooms.  Dystrophic lakes have high levels of humic matter and typically have yellow-brown, tea-coloured waters.
freshwater habitat with ecological classification of freshwater animals

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freshwater habitat with ecological classification of freshwater animals

  • 1. BY: MARIYAM NAZEER AGHA KUD NO: 15S14233 DEPT. OF STUDIES IN ZOOLOGY GOVT. ARTS AND SCIENCE COLLEGE, KARWAR
  • 2.  Introduction  Classification of freshwater ecosystem  Lentic ecosystem  Lentic system biota  Lotic ecosystem  Lotic system biota  Physical properties of freshwater  Chemical properties of freshwater  Biological properties of freshwater
  • 3.  Freshwater ecosystems are a subset of Earth's aquatic ecosystems. They include lakes and ponds, rivers, streams, springs, and wetlands. They can be contrasted with marine ecosystems, which have a larger salt content.  Freshwater habitats can be classified by different factors, including temperature, light penetration, and vegetation.  Freshwater ecosystems are particularly vulnerable to the different components of climate change.  Freshwater ecosystems can be divided into lentic ecosystems (still water) and lotic ecosystems (flowing water).
  • 4.  Lentic refers to stationary or relatively still water, from the Latin lentus, which means sluggish. Lentic waters range from ponds to lakes to wetlands, and much of this article applies to lentic ecosystems in general.  Lentic systems are diverse, ranging from a small, temporary rainwater pool a few inches deep to Lake Baikal, which has a maximum depth of 1740 m.  In addition, some lakes become seasonally stratified. Ponds and pools have two regions: the pelagic open water zone, and the benthic zone, which comprises the bottom and shore regions.  Since lakes have deep bottom regions not exposed to light, these systems have an additional zone, the profundal.  These three areas can have very different abiotic conditions and, hence, host species that are specifically adapted to live there.
  • 5.  Bacteria  Bacteria are present in all regions of lentic waters. Free-living forms are associated with decomposing organic material, biofilm on the surfaces of rocks and plants, suspended in the water column, and in the sediments of the benthic and profundal zones.  Primary producers  Algae, including both phytoplankton and periphyton are the principle photosynthesizers in ponds and lakes.  Phytoplankton are found drifting in the water column of the pelagic zone.  Many species have a higher density than water which should make them sink and end up in the benthos.  To combat this, phytoplankton have developed density changing mechanisms, by forming vacuoles and gas vesicles or by changing their shapes to induce drag, slowing their descent.  Invertebrates  Zooplanktons are tiny animals suspended in the water column. Like phytoplankton, these species have developed mechanisms that keep them from sinking to deeper waters, including drag-inducing body forms and the active flicking of appendages such as antennae or spines.  Fish and other vertebrates  Fish have a range of physiological tolerances that are dependent upon which species they belong to.  They have different lethal temperatures, dissolved oxygen requirements, and spawning needs that are based on their activity levels and behaviors.  Because fish are highly mobile, they are able to deal with unsuitable abiotic factors in one zone by simply moving to another.
  • 6.  Lotic refers to flowing water, from the Latin lotus, washed. Lotic waters range from springs only a few centimeters wide to major rivers kilometers in width.  The ecosystem of a river is the river viewed as a system operating in its natural environment, and includes biotic (living) interactions amongst plants, animals and micro-organisms, as well as abiotic (nonliving) physical and chemical interactions.  The following unifying characteristics make the ecology of running waters unique among aquatic habitats.  Flow is unidirectional.  There is a state of continuous physical change.  There is a high degree of spatial and temporal heterogeneity at all scales (microhabitats).  Variability between lotic systems is quite high.  The biota is specialized to live with flow conditions.
  • 7.  Bacteria  Bacteria are present in large numbers in lotic waters. Free-living forms are associated with decomposing organic material, biofilm on the surfaces of rocks and vegetation, in between particles that compose the substrate, and suspended in the water column.  Primary producers  Algae, consisting of phytoplankton and periphyton, are the most significant sources of primary production in most streams and rivers.  Phytoplankton float freely in the water column and thus are unable to maintain populations in fast flowing streams. They can, however, develop sizable populations in slow moving rivers and backwaters.  Insects and other invertebrates  Up to 90% of invertebrates in some lotic systems are insects.  These species exhibit tremendous diversity and can be found occupying almost every available habitat, including the surfaces of stones, deep below the substratum, adrift in the current, and in the surface film.  Insects have developed several strategies for living in the diverse flows of lotic systems.  Fish and other vertebrates  Fish are probably the best-known inhabitants of lotic systems. The ability of a fish species to live in flowing waters depends upon the speed at which it can swim and the duration that its speed can be maintained.  This ability can vary greatly between species and is tied to the habitat in which it can survive.  Continuous swimming expends a tremendous amount of energy and, therefore, fishes spend only short periods in full current.
  • 8.  Physical properties  Physical properties of aquatic ecosystems are determined by a combination of heat, currents, waves and other seasonal distributions of environmental conditions.  The morphometry of a body of water depends on the type of feature (such as a lake, river, stream, wetland, estuary etc.) and the structure of the earth surrounding the body of water. Lakes, for instance, are classified by their formation, and zones of lakes are defined by water depth.  Light interactions  Light zonation is the concept of how the amount of sunlight penetration into water influences the structure of a body of water. These zones define various levels of productivity within an aquatic ecosystems such as a lake. For instance, the depth of the water column which sunlight is able to penetrate and where most plant life is able to grow is known as the photic or euphotic zone. The rest of the water column which is deeper and does not receive sufficient amounts of sunlight for plant growth is known as the aphotic zone.  Thermal stratification  Similar to light zonation, thermal stratification or thermal zonation is a way of grouping parts of the water body within an aquatic system based on how each layer has different temperature variations. The less turbid the water, the more light is able to penetrate, and thus heating a thicker depth of water.  There are 3 main sections which define thermal stratification in a lake. The first is the epilimnion which is closest to the surface and experiences primarily wind circulation although the water is generally uniformally warm because of the close proximity to the surface.  The layer below is often called the thermocline and is an area within the water column which tends to experience a rapid decrease in temperature. Finally, the layer which is the bottom-most within the body of water is the hypolimnion which has uniformally cold water because of its depth which restricts sunlight from reaching it. In temperate lakes, fall-season cooling of surface water to 4 °C (the highest density of water) results in turnover of the water column.
  • 9. The chemical composition of water in a natural environment is influenced mainly by precipitation, type of soil and bedrock in the watershed, erosion, evaporation and sedimentation. All bodies of water have a certain composition of both organic and inorganic elements and compounds.  Water quality  There are hundreds of variables which are considered to play a role in water quality however a few have been determined to be of greater interest regarding the role they play in aquatic ecosystem health. While certain biological activities affect dissolved gas concentrations, nutrients, etc. human activity is one of the strongest influences on water quality.  Oxygen  Dissolved oxygen is an element which is necessary for a number of biological and chemical reactions which are critical to the proper functioning of the ecosystem. Some of the biological processes which alter the concentrations of dissolved oxygen include photosynthesis and aquatic organism respiration. Oxygen profile is based on similar principles as thermal stratification and light penetration. Dissolved oxygen levels are generally lower as you move deeper into the body of water because of the lower availability of light in those parts of the water.  Carbon dioxide  Dissolve oxygen and dissolved carbon dioxide are often discussed together due the role they both play in aquatic organism respiration. These organisms absorb dissolved oxygen from the water to use in respiration and expel carbon dioxide as a byproduct of this process. Carbon dioxide tends to have an inverse diurnal relationship with oxygen.  Other nutrients  Nitrogen and phosphorus are ecologically significant nutrients in aquatic systems. Nitrogen is generally present as a gas in aquatic ecosystems Most of these dissolved nitrogen compounds follow a seasonal pattern with greater concentrations in the fall and winter months compared to the spring and summer. Phosphorus has a different role in aquatic ecosystems as it is a limiting factor in the growth of phytoplankton because of generally low concentrations in the water. Dissolved phosphorus is also crucial to all living things, is often very limiting to primary productivity in freshwater, and has its own distinctive ecosystem cycling.
  • 10.  Lake trophic classification  Limnology (study of freshwater ecosystem), classifies lakes (or other bodies of water) according to the trophic state index.  An oligotrophic lake is characterised by relatively low levels of primary production and low levels of nutrients.  A eutrophic lake has high levels of primary productivity due to very high nutrient levels.  Eutrophication of a lake can lead to algal blooms.  Dystrophic lakes have high levels of humic matter and typically have yellow-brown, tea-coloured waters.