“biogeochemical cycle”的概念、定义、翻译、参考文献-科学参考

biogeochemical cycle

Biology

The cyclical movement of elements between living organisms (the biotic phase) and their nonliving (abiotic) surroundings (e.g. rocks, water, air). Examples of biogeochemical cycles are the carbon cycle, nitrogen cycle, oxygen cycle, phosphorus cycle, and sulphur cycle.

Geology and Earth Sciences

Movement of chemical elements from organism to physical environment to organism, in a more or less circular pathway. They are termed ‘nutrient cycles’ if the elements concerned are essential to life. An element may be solid, liquid, or gaseous, or form different chemical compounds, in the various parts of the cycle. Amounts in the inorganic reservoir pools are usually greater than those in the active pools. Exchange between the system components is achieved by physical processes (e.g. weathering) and/or biological processes (e.g. protein synthesis and decomposition). The latter form the vital negative-feedback mechanisms that regulate the cycles. Cycles may be described as varying from perfect to imperfect. A perfect cycle (e.g. the nitrogen cycle) has a readily accessible abiotic, usually gaseous, reservoir and many negative-feedback controls. By contrast, the phosphorus cycle, which has a sedimentary reservoir accessed only by slow-moving physical processes, has few biological feedback mechanisms. Human activities can disrupt these cycles, leading to pollution. Theoretically, perfect cycles are more resilient than imperfect cycles.

Geography

The cyclical movement of energy and materials within ecosystems. See W. Schlesinger (1997).

单词	biogeochemical cycle
释义	biogeochemical cycle Biology The cyclical movement of elements between living organisms (the biotic phase) and their nonliving (abiotic) surroundings (e.g. rocks, water, air). Examples of biogeochemical cycles are the carbon cycle, nitrogen cycle, oxygen cycle, phosphorus cycle, and sulphur cycle. Geology and Earth Sciences Movement of chemical elements from organism to physical environment to organism, in a more or less circular pathway. They are termed ‘nutrient cycles’ if the elements concerned are essential to life. An element may be solid, liquid, or gaseous, or form different chemical compounds, in the various parts of the cycle. Amounts in the inorganic reservoir pools are usually greater than those in the active pools. Exchange between the system components is achieved by physical processes (e.g. weathering) and/or biological processes (e.g. protein synthesis and decomposition). The latter form the vital negative-feedback mechanisms that regulate the cycles. Cycles may be described as varying from perfect to imperfect. A perfect cycle (e.g. the nitrogen cycle) has a readily accessible abiotic, usually gaseous, reservoir and many negative-feedback controls. By contrast, the phosphorus cycle, which has a sedimentary reservoir accessed only by slow-moving physical processes, has few biological feedback mechanisms. Human activities can disrupt these cycles, leading to pollution. Theoretically, perfect cycles are more resilient than imperfect cycles. Geography The cyclical movement of energy and materials within ecosystems. See W. Schlesinger (1997).
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