A tabular model for ecosystem development

A more general and complete summary of important changes in community structure and function in the sere, as revealed by the study of the large, open systems of nature, is showing this post....

Expected trends in the gradient from youth to maturity are grouped under several headings. Although ecologists have studied succession in many parts of the world most of the emphasis to date has been on the descriptive aspects such as the qualitative changes in species structure. Only recently have the functional aspects of succession also been considered. Consequently, some of the items listed in this post must be considered hypothetical in the sense that they are based on good experimental or theoretical evidence, but have not been verified by adequate data from the field. Five aspects seem most significant require a bit more explanation as follows.

The kinds of plants and animals that change continuously with succession. Those species that are important in the pioneer stages are not likely to be important in the climax. When the density of species in a sere is plotted against time, a characteristic stair – step graph is obtained, as illustrated in this post. Such a pattern usually is apparent whether we are considering a specific taxonomic group, such as birds, or a trophic group, such as herbivores or producers. Typically, some species in the gradient have wider tolerances or niche preferences than others and, therefore, persist over a longer period of time. Thus, in the terrestrial succession pictured in thispost pine trees and cardinals persist throush longer periods of time than do most of the other species. In general, the more species in the group (whether taxonomic or ecological) that are geographically available for colonization, the more restricted will be the occurrence of each species in the time sequence. This kind of regulatory adjustment is the result of competition coexistence interactions discussed in the next post.

Biomass and the standing crop of organic matter increase with succession. In both aquatic and terrestrial environments the total amount of living matter (biomass) and decomposing organic materials tend to increase with time. Also, many soluble substances accumulate; these include sugars, amino acids, and many organic products of microbial decomposition. These liquid products that leak out from the bodies of organisms are often collectively known as extra metabolites. Some of these substances provide food for microorganisms, and perhaps also for microorganisms. Other   substances are equally important in that they may act as inhibitors (antibiotics) or as growth promoters (as, for example, vitamins), sub stances produced by one organism may inhibit the further growth of that species (thus providing population self regulation, or they may act on completely different species. This was dramatically drought to our attention by the discovery of penicillin and other bacterial antibiotics produced by fungi. In other cases, increasing organic matter stimulates the growth of bacteria that manufacture vitamin B12, a necessary growth promoter for many animals (many are unable to manufacture this and other vitamins themselves). Where extra metabolites do prove to be regulatory, we would be justified in calling these substances environmental hormones since by definition a hormone is a ‘’chemical regulator.’’ Chemical regulation is one way of achieving community stability as the climax is approached, because the physical as well as the chemical perturbations (as, for example, light and water relations) are buffered by a large organic structure. There is no question that the increase in amount of and the change in organic structure are two of the main factors bringing about the change in species during ecological development.

The diversity of species tends to increase with succession. Initially this is the case, although it is not clear from the present data that  the change in variety of taxa follows the same pattern in all ecosystems. Increase in diversity of heterotrophs is especially striking; the variety of microorganisms and heterotrophic plants and animals is likely to be much greater in the later stages of succession than in the early stages. Maximum diversity of autotrophs in many ecosystems seems to be reached earlier in succession. The interplay of opposite trend makes it difficult to generalize in regard to diversity. The increase in size of individual organisms and the increase in competition tend to reduce diversity, while the increase in organic structure and variety of niches tends to increase it. As we have already pointed in the discussion of diversity in this post there may be an optimum level of diversity for a given energy flow pattern. We can state that, in general, rapid growth seral stages  will tend to have a low diversity on the order of 0.1 or 0.2 on the scale used in this post while mature stages will tend to have a higher level on the order of 0.7 or 0.8 unless there is a large energy subsidy that counteracts this patter.

A decrease in net community production and a corresponding increase in community respiration are two of the most striking and important trends in succession. These changes in community metabolisms are shown graphically in this post which compares ecosystem development in a small laboratory microcosm and in a large natural forest. Total production (PG ) increases faster than energy expenditure (P) at first, so a large net production (PN ) results in a rapid increase in biomass (B). gradually, equilibrium is established, in about 100 days in the microcosm and 100 or more years in the forest. Perhaps the best way to picture this overall trend is as follows; species, biomass, and the P/R ratio continue to change long after the maximum gross primary production possible for the site has been achieved. As one evidence for this we may cite the situation in regard to leaves in a terrestrial broadleaved succession. Agricultural scientists have repeatedly found that maximum productivity of broad leaved crops occurs when the leaf surface area exposed to the incoming light from above is about 4 or 5 times the surface area of the ground. Any increase in leaves beyond this level does not increase the photosynthetic rate per square mater, since increased shading cancels any advantage that might accrue from increased photosynthetic tissue. In fact, the increased respiration of the extra leaves that do not receive adequate light may reduce the net production of the crop. In a forest the leaf area apparently continues to increase far beyond that limit experimentally shown to increase gross production, since leaf area per ground is often 10 or more in an old forest. Since forests are among, the most successful of ecosystems with a long geological history of survival, we may well consider the possibility that the extra leaves have other important functions in the ecosystem in addition to production of food. The undoubtedly help moderature and moisture and provide reserves that are important during periods of climatic stress or insect of climatic stress or insect or disease attack.  

A tabular model for ecological succession of the autogenic, autotrophic type

Ecosystem characteristic
Trend in ecological development  early stage to climax
Or
youth to maturity
or
growth stage to steady state

Community structure
Species composition
Changes rapidly at first, then more gradually
Size of individuals
Tends to increase
Number species of autotrophs
Increases in primary and often early in secondary succession; may decline in older stages as size of individuals increases
Number species of heterotrophs
Increases until relatively late in the sere
Species diversity
Increases initially, then becomes stabilized or declines in older stages as size of individual increases
increases
Nonliving organic matter
increases

Energy flow (community metabolism)
Gross production (P)
Increases during early phase of primary succession; little or no increase during secondary succession
Net community production (yield)
decreases
Community respiration (R)
Increases
P/R ratio
P>R to P = R
P/B ratio
Decreases
B/P and B/R ratios (biomass supported/ unit energy)
increases
Food chains
From linear chains to more complex food webs

Biogeochemical cycles
Mineral cycles
Become more closed
Turnover time
increases
Role of detritus
increases
Nutrient conservation
increases


Natural selection and regulation

Growth form
From r – selection (rapid growth) to K – selection (feedback control)a
Quality of biotic components
increases
niches
Increasing specialization
Life cycles
Length and complexity increases
Symbiosis (living together)
Increasingly mutualistic
entropy
decreases
informationb
increases
Overall stability
increases

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