Nauru once possessed the world's purest deposits of rock phosphate, the precursor of the agricultural fertiliser, superphosphate. This resource was almost entirely depleted during the 20th century, mainly destined for Australia and New Zealand, where it played a critical role in the economic, social and demographic development of these nations and their biological transformation to outposts of temperate Northern Hemisphere flora.
By the early 1990s, the primary phosphate that had once blanketed the island had been almost completely removed, exposing a dramatic buried landscape of karst pinnacles and transforming Nauru into the world's most environmentally altered nation. Investigations into the rehabilitation of the mined-out area began in 1953, but all rejected the idea of restoration on the grounds of expense. In 1993, Nauru won an out-of-court settlement of A$135 million from Australia for restitution of the phosphate lands. No rehabilitation has yet taken place, however, and the project is unlikely to succeed. The soil stockpiled for the project is inadequate in quantity, in fertility, in elemental composition, in water retention capacity, and contains toxic levels of cadmium. Rainfall is too unreliable to support regular cultivation and the Nauruans possess no tradition of agriculture.
One alternative to rehabilitation is to exploit the terrain that has been exhumed from beneath the phosphate overburden. This closely resembles the Nauruan landscape of a quarter of a million years ago, before humans arrived and before phosphate buried the land. Such spitzkarren landscapes elsewhere in the tropics are venerated as landscape wonders and revered as scientific marvels. They are protected by World Heritage status and receive millions of visitors a year. The end of mining in Nauru is meanwhile leading to the re-establishment of an ecologically valuable and visually striking indigenous vegetation. This spectacular new landscape should be preserved, not destroyed, and exploited as a global travel destination. 相似文献
We measured tissue phosphorus content of high and low intertidal Hormosira banksii to test the hypothesis that tissue phosphorus content would be greater in individuals from the low intertidal because of greater total uptake associated with longer immersion in seawater. Moreover, we predicted that tissue phosphorus would be greater at sites where the seawater contained higher phosphate concentrations. There was a positive, linear relationship between local seawater phosphate concentrations and tissue phosphorus content of H. banksii from high and low intertidal zones at six different sites in winter. However, there were no comparable relationships in summer, even though the range of seawater phosphate concentration was similar in both seasons. The phosphorus contents of low intertidal H. banksii were significantly greater than high intertidal H. banksii in winter, but not in summer. Reasons for these differences may be related to greater access to seawater phosphate in low intertidal algae (than those in the high intertidal) in winter, followed by greater utilisation of the internal phosphorus between winter and summer, due to faster growth rates in the low intertidal. 相似文献
We investigated in more detail the adsorption phenomenon which was described earlier. It was clearly established that the hydroxyl apatite was not participated in P adsorption. This phenomenon takes place because of ferric hydroxide film. Modem sediments from the Southem Basin of Lake Baikal were taken and stirred with Baikal water. Carrier-free [^32p]-orthophosphate was added in this system. Similar experiments were made with carrier-free [^35S]-sulphate. Sulphate stayed in supematant completely. The influence of pH on the system with inorganic phosphate was also studied. In low alkali conditions phosphate migrated in supematant, in low acid, in sediments. Baikal sediment was stripped of iron-hydroxous film by treatment with 1% oxalic acid. Investigation of striped sediment shown that phosphate stays in supematant only. Hence, hydroxyl apatite cannot be the phase of the sediments of Lake Baikal which binds phosphate. This all showed by our group before. Now we have found the limit of phosphate sorption in Lake Baikal sediments and the stehiometry of the sorption. The sorption limit of Lake Baikal sediments was studied. An experiment with inorganic ^31P phosphate was made. 0.025% K2HPO4 solution with adding ^32P radioactive mark into it was prepared. 100 μL of mixture of ^31PO4^3- and ^32PO4^3- seven times were added in a "Baikal water-Baikal sediment" system and blank (100 ml BW only). Concentrations of inorganic ^31PO4^3- were very low so the bend dot on the diagram was found and sorption limit of sediment was estimated. Baikal sediment stopped assimilating phosphate in the bend dot. The stehiometry of sorption was estimated by supematant-sediment radioactive ratio, which equals 3, that is, three Fe (Ⅲ) atoms associate one PO4^3- anion. The only Fe (Ⅲ) substance which could associate P is -Fe-O-Fe- polymer film. It also dissolves in acid conditions. 相似文献
