Environmental Management: Principles and practice
part of a complex system and must fit in, obey the limits or be cut out. If humans
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5 2020 03 04!03 12 11 PM
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- Environmental catastrophes and changes
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part of a complex system and must fit in, obey the limits or be cut out. If humans upset Gaian mechanisms, there could be sudden, possibly catastrophic, runaway environmental changes. Environmental management must assess the reality of this threat and, if it is significant, monitor for and prevent runaway changes. Environmental catastrophes and changes The scale of catastrophes varies from local to global. They may happen every few years or be millions of years apart, and they may or may not have a predictable pattern of recurrence. Catastrophes may be sudden, obvious and gradual, or of the creeping form (where a system is stressed and changes virtually imperceptibly until a threshold is reached, whereupon there may be sudden drastic alteration). Given long enough, chance events probably affect the survival of organisms at least as much as evolution—the process has been described as ‘contingency’ (Gould, 1984). Events which challenge life but give insufficient time for adaptation would allow some organisms to prevail for quite fortuitous reasons (rather than ‘survival of the fittest’). Early earth scientists invoked catastrophic events to explain erosive land forms, prehistoric extinctions and geological unconformities (Thomas Huxley probably coined the term ‘catastrophism’ in 1869). With the publication of The Principles of Geology in 1830, Charles Lyell helped uniformitarianism (the idea of continuing gradual change, involving processes operating in the past that operate today) to prevail over catastrophism, but since the mid-nineteenth century there have been various attempts to revive it (Smith and Dawson, 1990; Ager, 1993). A number of scientists recognize mass extinctions, perhaps 15 significant events in the last 600 million years, the four major ones being: ca. 440 million years BP, ca. 390 million years BP, ca. 220 million years BP, and (the K/T boundary event) ca. 65 million years BP (Raup, 1988; 1993). The cause of mass extinctions is debated, and some question whether there really is adequate evidence, suggesting instead more gradual loss of species. In the early 1980s Walter Alvarez noted the widespread occurrence of iridium (a rare metal), glass spherules and ‘shocked quartz’ grains in a thin clay layer of K/ T boundary age (Alvarez and Asaro, 1990). This and tsunami beds around the Gulf of Mexico have been interpreted as evidence of a planetesimal (of roughly 10 km diameter) impacting with the Earth (Kerr, 1972). Others suggest that a very large sheet-lava eruption, possibly the outpouring of the Deccan Plateau Basalts of India caused the extinctions. These are by no means the only causes suggested by supporters of the K/T mass extinction. Others include: climate change, sea-level falls, reduction of atmospheric oxygen levels, disease, etc. Whether or not a planetesimal strike caused the extinction of the dinosaurs or caused earlier and subsequent disruptions, there is enough evidence of impacts to SCIENCE 149 indicate a threat that environmental managers should seriously consider. Over 100 ancient craters, a few of more than 100 km diameter, are known on Earth and some are as recent as 1500 BP (Huggett, 1990). A small body (estimated 100 metres diameter) probably exploded about 8 km up at Tunguska, Siberia, in AD 1908, flattening 1200 to 2200 km 2 of taiga forest. A similar strike may have occurred in South Island, New Zealand, ca. 800 BP (Hecht, 1991), and a blast (of about 100 kilotons yield) in the South Atlantic in 1978 may have been caused by a planetesimal (Lewin, 1992). The impact of a 1-km diameter body would probably endanger civilization. Volcanic eruptions can be locally devastating (e.g. Pompeii and Herculaneum —AD 79; Hekla, Iceland—AD 1636; Tambora, Indonesia—AD 1815; Krakatoa, Indonesia—AD 1883), and large outpourings of lava or eruptions of ash, gases and aerosols into the stratosphere could alter climate and cause acid fallout. Smaller eruptions like El Chichon (Mexico—1982) and Mt Pinatubo (Philippines—1991) caused temporary slight lowering of global temperatures. Palaeoecologists and archaeologists have correlated past eruptions, acid deposition in Greenland ice and alteration of climate affecting human fortunes in Europe. The recurrence of catastrophic events may not be random: planetesimal strikes, variation in Earth’s solar radiation receipts and perhaps vulcanicity and seismic activity might be more likely at certain alignments in the orbits of the planets or perhaps as the solar system passes the galactic plane every 26 to 33 million years. Velikovsky (1950; 1952; 1955) suggested that planetary alignments within the solar system could be blamed for catastrophic events. However, this, and a modern variant, the ‘nemesis’ hypothesis have won only limited support. The nemesis hypothesis, suggests that a hidden companion star to the Sun in an eccentric orbit periodically affects the solar system enough to alter climate and possibly trigger volcanicity. Download 6.45 Mb. Do'stlaringiz bilan baham: 
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