Environmental Management: Principles and practice
How stable are environments?
Download 6.45 Mb. Pdf ko'rish
|
5 2020 03 04!03 12 11 PM
|
How stable are environments?
Environmental management is likely to want to know whether an ecosystem is stable, and what would happen if it were disturbed. As discussed earlier, the concept of ecosystem stability has provoked much debate and is not fully resolved (Hill, 1987). Natural ecosystems are rarely static: the best environmental management can expect is a sort of dynamic equilibrium, not a fixed stability. Equilibrium is in part a function of sensitivity and resilience to change. Sensitivity may be defined as the degree to which a given ecosystem undergoes change as a consequence of natural or human actions. Resilience refers to the way in which an ecosystem can withstand change. Originally it was proposed as a measure of the ability of an ecosystem to adapt to a continuously changing environment without breakdown. It would be misleading to give the impression that these concepts, stability and resilience, are straightforward. There is disagreement as to whether an ecosystem evolves in the long term towards a steady-state with equilibrium of its biota through slow and steady evolution of species (phyletic gradualism) or generally steady slight and slow evolution punctuated by occasional sudden catastrophes and extinctions, after which there may comparatively rapid and considerable biotic change (punctuated equilibrium) (Gould, 1984; Goldsmith, 1990). Whatever the process, the end result is held to be a ‘climax stage’, reached via more or less transient successional stages (at any of which succession might be halted by some parameter) (Clements, 1916). Stability (some prefer to use ‘constancy’) is often invoked by those interested in establishing whether conditions will remain steady or will return via a predictable path to something similar to the initial steady-state after disturbance. It is widely held that ecosystem stability is related to biological diversity: the greater the variety of organisms there is in an ecosystem, the less likely is there to be change in biomass production, although population fluctuations of various species may still occur (Tilman, 1996). However, it is quite possible that a change in some parameter could CHAPTER SEVEN 146 have an effect on all organisms. Thus diversity may help ensure stability, but does not guarantee it. An ecosystem may not be stabilized when disturbed: it may be close to a starting-point, or it could be undergoing cyclic, more or less constant or erratic change. Return to a pre-disturbance state is therefore uncertain. Resilience is often measured by the speed of recovery of a disturbed ecosystem, but can refer to how many times a recovery can occur if disturbance is repeated (Holling, 1973). Topsoil, for example, has little resilience; easily lost, it may well take centuries to develop a new cover. An ecosystem may return to stability after several disturbances but fail to after a subsequent upset for various reasons. The concept of resilience has been applied to human ecology: some societies absorb or resist social change and continue with traditional skills and land uses or develop satisfactory new ones; other societies fail and their resource use and livelihood strategies degenerate. Referring to sensitivity and resilience, Blaikie and Brookfield (1987:11) suggested a simple classification of land, which may be modified to apply to ecosystems in general: 1 Ecosystems of low sensitivity and high resilience These only suffer degradation under conditions of poor management or natural catastrophe. Generally these are the best ecosystems to stretch to improve production of food or other commodities. 2 Ecosystems of high sensitivity and high resilience These suffer degradation easily but respond well to management and rehabilitation efforts. 3 Ecosystems of low sensitivity and low resilience These initially resist degradation but, once a threshold is passed, it is difficult for any management and restoration efforts to save things. 4 Ecosystems of high sensitivity and low resilience These degrade easily and do not readily respond to management and rehabilitation efforts. It is probably best either to leave such ecosystems alone or to alter them radically—for example, forest might be converted to rice paddyfield and suffer less ongoing degradation than if it were converted to tree crops. Managers or researchers often wish to establish in advance, or sometimes after a disturbance, what the consequences will be: (a) Will the ecosystem re-establish its initial state? (b) Will there be a shift to a new state? (c) If (a) takes place, how rapid will the recovery be and how complete? (d) What path does the recovery take? (e) How often can recovery occur? (f) Will the same recovery path always be followed? (g) Will successive, similar disturbance have the same effect? (h) Would change still occur if there were no disturbance? SCIENCE 147 Some ecosystems are in constant non-equilibrium or frequent flux, rather than in a stable state at or near carrying capacity. The behaviour of an ecosystem (physical or human) can be modelled. However, there is often such complexity that the outcome is difficult to predict reliably with simple systems analysis. Succession may not be as reliable and useful a concept as some would like. In particular, ecological change may not be as predictable as might be wished. For example, in some environments heavy grazing leads to increased scrub cover; a reduction of grazing might be expected to lead to a reduction of the scrub because it sometimes causes a thickening of the woody vegetation. Some plant communities do not exhibit succession as a directional change but follow a cyclic fluctuation about a mean (the classic case being bog or tundra hummock formations) (Kershaw, 1973:65–84). Download 6.45 Mb. Do'stlaringiz bilan baham: 
|