Geochemistry. William M. White
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The core, as we noted earlier, consists of iron-nickel alloy. You might ask how can we be confident about the composition of something we have never sampled and have no prospect of ever sampling? The answer is again the geophysical constraints, which tell us that the core is very dense, and the composition of chondrites, which tell us that the only elements of sufficient abundance and density to form the core are iron and nickel. That conclusion is reinforced by iron meteorites, most of which are cores of asteroids. There is a problem, however; namely, that any combination of iron and nickel will be denser than the Earth's core at relevant temperatures and pressures. These elements must thus be diluted with perhaps some 5% or so of one or more lighter elements. The meteorite inventory of what was available and the isotopic composition of some of the candidate light elements, such as silicon, helps us narrow the possibilities, but we do not yet have a firm answer. Experiments showing how elements partition between silicate and iron liquids together with thermodynamics places important constraints on what is possible. Comparing the composition of the mantle with that of chondritic meteorites show that the mantle is highly depleted in elements, including the most valuable metals such as platinum and gold, that we expect to partition into iron liquid and since this partitioning is temperature and pressure dependent, we can begin to develop scenarios on how the core formed.
Then we turned to the crust, first the oceanic crust, then to the continental crust. The first question is its composition, an easier one to answer than the composition of mantle and core. It is not an easy task, however, given how heterogeneous the crust is and while the surface is easily sampled, the lower crust is not. Nevertheless, we continue to build on the work of Clark and Goldschmidt and refine estimates of crustal composition. Then we turn our attention to how the crust formed. We can certainly establish that the continental crust has formed through partial melting of the mantle, but in what tectonic environment under what circumstances, and when? Did it form early in Earth's history, steadily through time or in pulses, or perhaps only recently? And how permanent is it? We know a lot, but we're still struggling to completely answer these questions.
Life is, of course, ubiquitous at the surface of the Earth and has modified the planet in remarkable ways: life is a geologic force. Organisms produce a vast array of chemicals that find their way into the physical environment. As we noted, modern geochemistry differs from what Schönbein envisioned in that it encompasses organic as well as inorganic matter, and these organic substances are ubiquitous at the surface of the Earth. This is the subject to which we turn in Chapter 12. After briefly exploring the nature and structure of organic compounds and the role they play in life, we'll survey their presence in soils and natural waters. Once outside a cell, organic substances are subject to attack by microbes and begin to degrade almost immediately. Yet some can survive on millennial time scales and longer. An emerging paradigm emphasizes the importance of adsorption of mineral surfaces in resisting degradation. The ability of dissolved organic molecules to adsorb complex inorganic substances is important: it retains nutrients in soil and maintains otherwise insoluble metals in solution. Some of these long surviving molecules, or at least their hydrocarbon skeletons, can be associated with specific biomolecules. Some of these biomarkers, or chemical fossils, are restricted to specific groups of organisms and can thus help us reconstruct past environments and biological evolution. Others have proved useful in reconstructing past atmospheric CO2 levels and paleotemperatures.
Organic substances are an important part of the carbon cycle. Photosynthesis and subsequent sequestration of organic matter in sedimentary rocks transformed the Earth's initial CO2-rich atmosphere to one containing free oxygen, which first occurred 2.3 billion years ago in the Great Oxidation Event. For the next billion and a half years, some atmospheric oxygen was present, but not enough to support metazoans (animals). Then around 600 million years ago, atmospheric oxygen levels began to rise again and just at this time the first animals appear in the fossil record. But as oxygen was produced, atmospheric CO2 was drawn down. As a greenhouse gas, CO2 plays a critically important role governing climate and the times oxygen rose in the atmosphere were accompanied by glaciations in the Proterozoic and Paleozoic.
This was not the cause of the Pleistocene glaciations, however. Stable isotope studies demonstrated that glacial-interglacial cycles correlated with small changes in the Earth's orbit and rotation (the Milankovitch variations). These were the pacemaker of the Pleistocene glacial cycles, but it was shuffling of CO2 between the atmosphere and oceans that actually caused the climate swings.
Burial of organic carbon in sediments has also produced the coal and petroleum that have provided the energy to power the global economy since the Industrial Revolution. We'll examine the processes that transform this buried organic matter into these energy resources. But in burning fossil fuels we are increasing atmospheric CO2, which, not surprisingly, is warming the planet and initiating a host of other climate changes.
In Chapter 13, we will focus attention on the Critical Zone, which is the land surface from the top of vegetation to the bottom of circulating groundwater. It is so called because essentially all terrestrial life lives within it and ultimately all life, including marine life, depends on processes occurring within this zone. It is here that rock comes in contact with water and air, and primary minerals are replaced by new ones. These weathering reactions produce soil and release nutrients that make terrestrial life possible. Some fraction of these nutrients is carried to the oceans by streams and rivers and make marine life possible. Life is an integral part of the weathering and soil development process, as organic acids help to break down rock and movements of metals complexed by organic molecules contribute to the development of distinct soil horizons over time.
Weathering of silicate rocks is another important part of the carbon cycle and consequently influences climate on time scales of tens to hundreds of millions of years. This is because carbonic acid produced by dissolution of CO2 in water provides most of the acidity necessary to drive weathering reactions. The result is a solution enriched in calcium and bicarbonate, which is then carried to the oceans by streams and rivers to be precipitated as carbonate sediment, thus removing CO2 from the atmosphere until it is again released by metamorphism or volcanism to the atmosphere as CO2. Over Earth's history, there has been a net transfer of CO2 from the atmosphere to sedimentary carbonate, keeping Earth's surface temperature within the habitable range even as the Sun has grown steadily brighter. We'll examine weathering reactions and their rates from the perspective of field studies. We'll find that lithology, climate and hydrology, topography, and the biota all exert important controls on weathering rates. We'll then turn our attention to the composition of streams and rivers and see how these same factors control the composition of streams and rivers. Finally, we look at the composition of saline lakes and see how the process of fractional crystallization leads to a great diversity of their compositions.
In Chapter 14, we follow the rivers to where they lead: the oceans. The oceans are salty and alkaline because, as Anton Lavoisier put it, they are “the rinsings of the Earth,” that is, they contain the weathering products of the land surface. Just six components, Na+, Mg2+, Ca2+, K+, Cl–, and