Thursday, August 15, 2019
A Freshwater Aquatic and Terrestrial Food Web
ââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬â- Food web From Wikipedia, the free encyclopedia Aà freshwaterà aquaticà andà terrestrialà food web. Aà food webà (orà food cycle) depicts feeding connections (what eats what) in anà ecological communityand hence is also referred to as aà consumer-resource system. Ecologists can broadly lump all life forms into one of two categories calledà trophic levels: 1) theà autotrophs, and 2) theà heterotrophs. Toà maintaintheir bodies, grow, develop, and toà reproduce, autotrophs produceà organicà matter fromà inorganicsubstances, including bothà mineralsà andà gasesà such asà carbon dioxide.Theseà chemical reactionsrequireà energy, which mainly comes from theà sunà and largely byà photosynthesis, although a very small amount comes fromà hydrothermal ventsà andà hot springs. A gradient exists between troph ic levels running from complete autotrophs that obtain their sole source of carbon from the atmosphere, toà mixotrophs(such asà carnivorous plants) that are autotrophic organisms that partially obtain organic matter from sources other than the atmosphere, and completeà heterotrophsà that must feed to obtain organic matter.The linkages in a food web illustrate the feeding pathways, such as where heterotrophs obtain organic matter by feeding on autotrophs and other heterotrophs. The food web is a simplified illustration of the various methods of feeding that links an ecosystem into a unified system of exchange. There are different kinds of feeding relations that can be roughly divided intoà herbivory,à carnivory,à scavengingà andparasitism. Some of the organic matter eaten by heterotrophs, such asà sugars, provides energy.Autotrophs and heterotrophs come in all sizes, fromà microscopicà to manyà tonnesà ââ¬â fromà cyanobacteriaà togiant redwoods, and fromà virusesà andà bdellovibrioà toà blue whales. Charles Eltonà pioneered the concept of food cycles, food chains, and food size in his classical 1927 book ââ¬Å"Animal Ecologyâ⬠; Elton's ââ¬Ëfood cycle' was replaced by ââ¬Ëfood web' in a subsequent ecological text. Elton organized species intoà functional groups, which was the basis forà Raymond Lindeman's classic and landmark paper in 1942 on trophic dynamics.Lindeman emphasized the important role ofà decomposerà organisms in aà trophic system of classification. The notion of a food web has a historical foothold in the writings ofà Charles Darwinà and his terminology, including an ââ¬Å"entangled bankâ⬠, ââ¬Å"web of lifeâ⬠, ââ¬Å"web of complex relationsâ⬠, and in reference to the decomposition actions of earthworms he talked about ââ¬Å"the continued movement of the particles of earthâ⬠. Even earlier, in 1768à John Brucknerà described nature as ââ¬Å"one contin ued web of lifeâ⬠. ââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬â-Food webs are limited representations of real ecosystems as they necessarily aggregate many species intoà trophic species, which are functional groups of species that have the same predators and prey in a food web. Ecologists use these simplifications inà quantitativeà (or mathematical)à modelsà of trophic orconsumer-resource systemsà dynamics. Using these models they can measure and test for generalized patterns in the structure of real food web networks. Ecologists have identified non-random properties in theà topographicà structure of food webs. Published examples that are used inà meta analysisà are of variable quality with omissions.However, the number of empirical studies on community webs is on the rise and the mathematical treatment of food webs usingnetwork theoryà had identified patterns that are comm on to all. Scaling laws, for example, predict a relationship between the topology of food web predator-prey linkages and levels ofà species richness. Trophic levels Main article:à Trophic level A trophic pyramid (a) and a simplified community food web (b) illustrating ecological relations among creatures that are typical of a northernà Borealà terrestrial ecosystem. The trophic pyramid roughly represents the biomass (usually measured as total dry-weight) at each level.Plants generally have the greatest biomass. Names of trophic categories are shown to the right of the pyramid. Some ecosystems, such as many wetlands, do not organize as a strict pyramid, because aquatic plants are not as productive as long-lived terrestrial plants such as trees. Ecological trophic pyramids are typically one of three kinds: 1) pyramid of numbers, 2) pyramid of biomass, or 3) pyramid of energy. [4] Food webs have trophic levels and positions. Basal species, such as plants, form the first level a nd are the resource limited species that feed on no other living creature in the web.Basal species can be autotrophs ordetritivores, including ââ¬Å"decomposing organic material and its associated microorganisms which we defined as detritus, micro-inorganic material and associated microorganisms (MIP), and vascular plant material. ââ¬Å"[11]:94à Most autotrophs capture the sun's energy inà chlorophyll, but some autotrophs (theà chemolithotrophs) obtain energy by the chemical oxidation of inorganic compounds and can grow in dark environments, such as the sulfur bacteriumà Thiobacillus, which lives in hotà sulfur springs.The top level has top (or apex) predators which no other species kills directly for its food resource needs. The intermediate levels are filled with omnivores that feed on more than one trophic level and cause energy to flow through a number of food pathways starting from a basal species. [12] ââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬â ââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬â- In the simplest scheme, the first trophic level (level 1) is plants, then herbivores (level 2), and then carnivores (level 3). The trophic level is equal to one more than the chain length, which is the number of links connecting to the base.The base of the food chain (primary producers orà detritivores) is set at zero. [3][13]à Ecologists identify feeding relations and organize species into trophic species through extensive gut content analysis of different species. The technique has been improved through the use of stable isotopes to better trace energy flow through the web. [14]à It was once thought that omnivory was rare, but recent evidence suggests otherwise. This realization has made trophic classifications more complex. [15] Energy flow and biomass Main article:à Energy flow (ecology) See also:à Ecological efficiencyThe Law of Conservation of Mass dates from Antoine Lavoisier's 1789 discovery that ma ss is neither created nor destroyed in chemical reactions. In other words, the mass of any one element at the beginning of a reaction will equal the mass of that element at the end of the reaction. [24]:11 Left:à Energy flow diagram of a frog. The frog represents a node in an extended food web. The energy ingested is utilized for metabolic processes and transformed into biomass. The energy flow continues on its path if the frog is ingested by predators, parasites, or as a decayingà carcassà in soil.This energy flow diagram illustrates how energy is lost as it fuels the metabolic process that transform the energy and nutrients into biomass. Right:à An expanded three link energy food chain (1. plants, 2. herbivores, 3. carnivores) illustrating the relationship between food flow diagrams and energy transformity. The transformity of energy becomes degraded, dispersed, and diminished from higher quality to lesser quantity as the energy within a food chain flows from one trophic s pecies into another. Abbreviations: I=input, A=assimilation, R=respiration, NU=not utilized, P=production, B=biomass. 25] Food webs depict energy flow via trophic linkages. Energy flow is directional, which contrasts against the cyclic flows of material through the food web systems. [26]à Energy flow ââ¬Å"typically includes production, consumption, assimilation, non-assimilation losses (feces), and respiration (maintenance costs). ââ¬Å"[5]:5à In a very general sense, energy flow (E) can be defined as the sum ofmetabolicà production (P) and respiration (R), such that E=P+R. The mass (or biomass) of something is equal to its energy content. Mass and energy are closely intertwined.However, concentration and quality of nutrients and energy is variable. Many plant fibers, for example, are indigestible to many herbivores leaving grazer community food webs more nutrient limited than detrital food webs where bacteria are able to access and release the nutrient and energy stores. [ 27][28]â⬠Organisms usually extract energy in the form of carbohydrates, lipids, and proteins. These polymers have a dual role as supplies of energy as well as building blocks; the part that functions as energy supply results in the production of nutrients (and carbon dioxide, water, and heat).Excretion of nutrients is, therefore, basic to metabolism. ââ¬Å"[28]:1230-1231à The units in energy flow webs are typically a measure mass or energy per m2à per unit time. Different consumers are going to have different metabolic assimilation efficiencies in their diets. Each trophic level transforms energy into biomass. Energy flow diagrams illustrate the rates and efficiency of transfer from one trophic level into another and up through the hierarchy. [29][30] ââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬â-It is the case that theà biomassà of eachà trophic levelà decreases from the base of the chain to the top. This is because energy is lost to the environment with each transfer asà entropyà increases. About eighty to ninety percent of the energy is expended for the organismââ¬â¢s life processes or is lost as heat or waste. Only about ten to twenty percent of the organismââ¬â¢s energy is generally passed to the next organism. [31]à The amount can be less than one percent in animals consuming less digestible plants, and it can be as high as forty percent inà zooplanktonà consumingà phytoplankton. 32]à Graphic representations of the biomass or productivity at each tropic level are calledà ecological pyramidsà or trophic pyramids. The transfer of energy from primary producers to top consumers can also be characterized by energy flow diagrams. [33] Food Web Aà food webà is a graphical description of feeding relationships among species in anà ecological community, that is, of who eats whom (Fig. 1). It is also a means of showing howà energyà and materials (e. g. ,à carbon) flow through a community ofà speciesà as a result of these feeding relationships.Typically, species are connected by lines or arrows called ââ¬Å"linksâ⬠, and the species are sometimes referred to as ââ¬Å"nodesâ⬠in food web diagrams. Relationships between soil food web, plants, organic matter, and birds and mammals. ââ¬Å"Theà herbivoresà are usually preyed upon by carnivores, which get theà energyà of theà sunlightà at third-hand, and these again may be preyed upon by other carnivores, and so on, until we reach an animal which has no enemies, and which forms, as it were, a terminus on this food cycle. There are, in fact, chains of animals linked together by food, and all dependent in the long run upon plants.We refer to these as ââ¬Ëfood-chains', and to all the food chains in a community as the ââ¬Ëfood-cycle. ââ¬Ëâ⬠A food web differs from a food chain in that the latter shows only a portion of the food web involving a simple, linear series of species (e. g. ,à predator,à herbivore,à plant) connected by feeding links. A food web aims to depict a more complete picture of the feeding relationships, and can be considered a bundle of many interconnected food chains occurring within the community. All species occupying the same position within a food chain comprise a trophic level within the food web.For instance, all of the plants in the foodweb comprise the first or ââ¬Å"primary producerâ⬠tropic level, allà herbivoresà comprise the second or ââ¬Å"primary consumerâ⬠trophic level, and carnivores that eatà herbivoresà comprise the third or ââ¬Å"secondary consumerâ⬠trophic level. Additional levels, in which carnivores eat other carnivores, comprise a tertiary trophic level. Elton emphasized early on that food chains tend to show characteristic patterns of increasing body size as one moves up the food chain, for example fromà phytoplanktonà to inv ertebrate grazers to fishes, or from insects to rodents to larger carnivores like foxes.Because individuals of small-bodied species require lessà energyà and food than individuals of larger-bodied species, a given amount ofenergyà can support a greater number of individuals of the smaller-bodied species. Hence, ecological communities typically show what Elton called a pyramid of numbers (later dubbed the Eltonian pyramid), in which the species at lower trophic levels in the food web tend to be more numerous than those at higher trophic levels.A second reason for the pyramid of numbers is low ecological efficiency: someà energyà is lost at each transfer between consumer and prey, such that theenergyà that reaches top predators is a very small fraction of that available in the plants at the base of the food web. Although there is wide variation among types ofà organismsà and types ofà ecosystems, a general rule of thumb is that availableà energydecreases by about a n order of magnitude at each step in the food chain.That is, only about 10% of theenergyà harvested by plants is consumed and converted into herbivoreà biomass, only 10% of that makes it intoà biomassà of primary carnivores, and so on. Thus, the structure of food webs is dictated in part by basic constraints set byà thermodynamics. The predictable dissipation ofà energyà at each step in food chains is one of the factors thought to limit the length of most food chains to a maximum of four or five steps. Cohen et al. (2003) emphasized that the correlations mong body size, abundance, and trophic level produce a characteristic trivariate structure to (pelagic) food webs (Fig. 2). The pyramid of numbers is less obvious at the most basal levels in terrestrial communities based on trees, which are typically much larger than theherbivoresà that feed on them. Pyramids of numbers orà biomassà may even be inverted in cases where the microscopic plants that support the web s how very rapid turnover, that is, where they grow and are eaten so rapidly that there is less plantà biomassà than herbivoreà biomassà present at a given time. ââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬â-Decomposers are an assemblage of smallà organisms, including invertebrates,à fungi, andà bacteria, that do not fit neatly into any trophic level because they consume deadà biomassà of organisms from all trophic levels. Decomposers are a critical component of the food web, however, because they recycle nutrients that otherwise would become sequestered in accumulating detritus. All food chains in a community constitute a food web. Aà food web is simply the total set of feeding relationship amongst and between the species composing a biotic community. These relationships may achieve considerable complexity.With many food chains and cross connecting links, there is greater opportunit y for the prey and predator population in an ecosystem to adjust to the changes. ââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬âââ¬â- The producer-consumer arrangement is one kind of structure known as trophic structure(trophic = food) and each food (nutritional) level in the food chain is called trophic levelà or energy level. The first trophic level in an ecosystem is occupied by the plants-producers (green plant-primary producers), because they utilize solar energy which is transformed to chemical form during photosynthesis.The energy stored in food or green plants is consumed by the plant eaters (herbivores) which make the second trophic level. Herbivores are also called primaryconsumers. Primary consumers in turn are eaten by carnivores (also known as secondary consumers) which occupy third trophic level. Secondary consumers (Primary carnivores) may be eaten by other carnivores (secondary or top carn ivores) which are known as tertiary consumers and occupy fourth trophic level. Decomposer occupy fifth trophic level in an ecosystem.Food Web- In nature, food chain relationships are very complex. They never operate as isolated sequences, as one organism may form the food source of many organisms and so on. Thus, instead of a food chain, a number of food chains are interconnected with each other and form a web-like structure known as ââ¬Ëfood web'. For example, grass may be grazed by grasshoppers as well as cattle, rabbits and each of these may be eaten by different type of carnivores, such as birds, toads, snakes, foxes, depending on their food habit.Thus, a particular organism may not occupy the same tropic level in every food chain; it may simultaneously behave as secondary, tertiary or a top consumer. Organisms, whose food is obtained from plants by the same number of steps are said to belong to the same tropic level. Thus, green plants occupy the first tropic level or the pr oducer level. The plant grazers occupy the second tropic level or primary consumer or herbivore level (all plant-grazing insects, cattle, deer, rabbits, etc. ).Flesh-eaters, that eat herbivores, form the third tropic level or the secondary consumer or carnivore level-1 (frogs, small fish, etc. ). The third tropic level is the tertiary consumer or carnivore level-2, which eats the flesh of herbivores and secondary consumers. In a similar fashion, tropic levels can be expanded based on the food habits of organisms. Charles Elton, a British ecologist, however, concluded that the number of links in a food chain rarely exceeds five, because in the process of energy transfer there is always the loss of energy to the environment.It is the energy transfer mechanism which determines the number of links in a food chain. Man and many other animals who are omnivores occupy different tropic levels in food chains in relation to pure carnivores. The food web maintains the stability of the eco-syst em. For example, green land can be grazed by different organisms like insects, rabbits, rodents, etc. The insects then can be eaten by frogs which can be eaten by snakes. Snakes can either be eaten by hawks
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