Kastner M
Scripps Institution of Oceanography, University of California-San Diego, La Jolla, CA 92093-0212, USA.
Proc Natl Acad Sci U S A. 1999 Mar 30;96(7):3380-7. doi: 10.1073/pnas.96.7.3380.
The chemical and isotopic compositions of oceanic biogenic and authigenic minerals contain invaluable information on the evolution of seawater, hence on the history of interaction between tectonics, climate, ocean circulation, and the evolution of life. Important advances and greater understanding of (a) key minor and trace element cycles with various residence times, (b) isotopic sources and sinks and fractionation behaviors, and (c) potential diagenetic problems, as well as developments in high-precision instrumentation, recently have been achieved. These advances provided new compelling evidence that neither gradualism nor uniformitarianism can explain many of the new important discoveries obtained from the chemistry and isotopic compositions of oceanic minerals. Presently, the best-developed geochemical proxies in biogenic carbonates are 18O/16O and Sr/Ca ratios (possibly Mg/Ca) for temperature; 87Sr/86Sr for input sources, Cd/Ca and Ba/Ca ratios for phosphate and alkalinity concentrations, respectively, thus also for ocean circulation; 13C/12C for ocean productivity; B isotopes for seawater pH;, U, Th isotopes, and 14C for dating; and Sr and Mn concentrations for diagenesis. The oceanic authigenic minerals most widely used for chemical paleoceanography are barite, evaporite sulfates, and hydrogenous ferromanganese nodules. Marine barite is an effective alternative monitor of seawater 87Sr/86Sr, especially where carbonates are diagenetically altered or absent. It also provides a high-resolution record of seawater sulfate S isotopes, (evaporite sulfates only carry an episodic record), with new insights on factors affecting the S and C cycles and atmospheric oxygen. High-resolution studies of Sr, Nd, and Pb isotopes of well-dated ferromanganese nodules contain invaluable records on climate driven changes in oceanic circulation.
海洋生物源和自生矿物的化学及同位素组成包含了有关海水演化的宝贵信息,从而也包含了有关构造、气候、海洋环流以及生命演化之间相互作用历史的信息。最近,在以下方面取得了重要进展并增进了理解:(a) 具有不同停留时间的关键微量元素循环;(b) 同位素源和汇以及分馏行为;(c) 潜在的成岩问题,以及高精度仪器的发展。这些进展提供了新的有力证据,表明渐变论和均变论都无法解释从海洋矿物的化学和同位素组成中获得的许多新的重要发现。目前,生物成因碳酸盐中最成熟的地球化学指标是用于温度的18O/16O和Sr/Ca比率(可能还有Mg/Ca);用于输入源的87Sr/86Sr;分别用于磷酸盐和碱度浓度从而也用于海洋环流的Cd/Ca和Ba/Ca比率;用于海洋生产力的13C/12C;用于海水pH值的B同位素;用于测年的U、Th同位素和14C;以及用于成岩作用的Sr和Mn浓度。在化学古海洋学中最广泛使用的海洋自生矿物是重晶石、蒸发硫酸盐和水成铁锰结核。海洋重晶石是海水87Sr/86Sr的有效替代监测指标,特别是在碳酸盐发生成岩蚀变或不存在的地方。它还提供了海水硫酸盐S同位素的高分辨率记录(蒸发硫酸盐仅携带间歇性记录),对影响S和C循环以及大气氧气的因素有了新的认识。对年代测定良好的铁锰结核的Sr、Nd和Pb同位素的高分辨率研究包含了有关气候驱动的海洋环流变化的宝贵记录。