Environmental Management: Principles and practice
Holdridge Life Zone Model
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5 2020 03 04!03 12 11 PM
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- Ecological stability
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Holdridge Life Zone Model
The Holdridge Life Zone Model is a widely used eco-climatic classification system, based on the relationship of current vegetation biomes to three general climatic parameters: annual temperature, annual precipitation and estimated potential evapotranspiration. It is an approach often used in land use classification. The model predicts eco-climatic areas but does not directly model actual vegetation or land cover distribution (Holdridge, 1964). Ecological stability Ecosystems adjust to perturbation through regulatory mechanisms. When the relationship between input and output to the system is inverse (e.g. increased sunlight causes more cloud, which reduces the impact of that sunlight on the surface), it is termed a negative feedback. The opposite is a positive feedback, whereby an effect is magnified (e.g. global warming might release methane hydrates trapped in the ocean causing increased warming). There is a risk that a positive feedback could result in an uncontrollable runaway reaction affecting a critical biogeochemical or biogeophysical cycle, so one of the tasks of environmental management should be to warn of such threats. The environmental manager needs to know whether the environment and ecological processes are stable (Smith, 1996). It is widely held that, given long enough, a steady state will be reached by an ecosystem because a web of relationships will allow it to adjust to serious localized or moderate widespread disturbances. Such an ecosystem should remain in steady state unless a critical parameter alters sufficiently. If change then occurs, it is termed ‘ecological succession’ or ‘biotic development’. Over a very long period of time organisms may evolve to an evolutionary maturity; over a shorter period a successional maturity may be reached before such evolution can occur (Johnson and Steere, 1974:8) The concept of ecological succession, pioneered by Clements (1916), is complex and still debated. According to the concept, organisms occupying an environment may modify it, sometimes assisting others—a birch wood may act as a nursery for a pine forest, which ultimately replaces the birch—thus birch is a successional stage en route to a pine stage. These transitional stages leading to a mature climax community are known as seres. Each vegetational stage or sere will have a characteristic assemblage of macrofauna and micro-organisms. Two types of succession are recognized: (1) primary succession and (2) secondary succession. The former is the sequential development of biotic communities from a bare lifeless SCIENCE 141 area (the site of a fire, volcanic ash, newly deglaciated land, etc). The latter is the sequential development of biotic communities from an area where the environment has been altered but has not had all life destroyed (cut forest, abandoned farmland, land that has suffered a flood or been lightly burnt, etc). Where succession is taking place from a bare area, the first stage is known as the pioneer stage, although in practice the expression may be applied to growth taking place in areas that do have some life—such as regrowth after logging (natural forests may be assumed to maintain maturity, rather than becoming senile and degenerating, through ‘patch and gap’ dynamics—clearings caused by storms, etc., that allow regeneration). Pioneer communities have a high proportion of plants and animals that are hardy, have catholic niche demands, and disperse well (weeds with wind-carried seeds, insects which can fly, etc). Mature, climax communities are supposed to have more species diversity, recycle dead matter better, and be more stable. Many communities do not reach maturity before being disturbed by natural forces or humans. It is often argued that an ecosystem with greater species diversity is more stable than one with less. In practice many variables are involved in determining ecosystem stability, and in a given situation the path of succession can be unpredictable (Figure 7.4). Until quite recently, the world population was non-urban; now, after rapid urbanization since the 1800s, over 50 per cent of people live in cities, and the FIGURE 7.4 Abrupt boundary between cleared lowland tropical rainforest and young oil- palm plantation, Peninsular Malaysia. A contrast between rich diversity of plant species in the forest, and the oil-palm/ground-cover species (planted to try to reduce erosion and weed growth) of the plantation CHAPTER SEVEN 142 percentage is increasing, Many of the largest, fastest growing cities are in poor countries and pose severe environmental problems. Even in developed countries urban growth is a challenge for environmental management. In recent years there has been a shift in interest from just coping with city problems to seeking strategies for ‘sustainable cities’—however, there is a long way to go before there are practical solutions in most, if not all, countries. Engineering and institutional developments alone will not provide solutions for urban transport, water supply, sanitation, control of crime, improving social cohesion, etc. For effective environmental management there must be better understanding of urban and peri-urban environments, societies and economies and how they interact with rural surroundings. Download 6.45 Mb. Do'stlaringiz bilan baham: 
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