In scientific usage, Earth’s sediment is best divided into three end-members:

These simple divisions are robust enough to include even the highly esoteric sediment forms that are turning up in the wider Solar System, like the solid ice particles transported and deposited by liquid methane on Titan.Ofcourse there are unusual, hybridormixed origins for some sediment but these can easily be accommodated (e.g. bioclastic, volcaniclastic). Note that the classification is restricted to grains that were sedimented; there are sedimentary horizons in the stratigraphic record that originated as precipitates below the deposited sediment surface, often bacteri-ally controlled. These were never sedimented as such and are considered as secondary or diagenetic sediments that post-dated physical deposition of host primary sediment. Deposited sediment accumulates as successive layers, termed strata, and such deposits as a whole are said to be stratified. The succession of strata in any given deposit is controlled by environmental factors and their correct interpretation involves a deep understanding of how present and past environments have evolved over time.

The chemical and biochemical processes that produce sediment also give other soluble byproducts; these chemical species control oceanic and atmospheric composition and provide long-term sourcing for base cations that nourish plant life and counteract acid deposition in temperate forested catchments. Chemical earth-surface processes have undoubtedly changed over deep geological time, in response to atmospheric and hydrological changes, whilst biological processes have changed hand-in-hand with organic evolution. By this view, sediment production is an accident of weathering and evolution—a waste product. Ever since the Archaean, the planet has ‘learnt’ how to cope with this waste, just like it has with the waste oxygen produced during plant photosynthesis. There was no predeterminism associated with the processes of sediment production on early Earth or any other planet. Sediment simply fell out (forgive the pun) of the rock cycle in which primary rock is chemically and physically altered. Compare for example sediment on the Moon with the Earth.In the former the sediment is a fragmented remnant from past meteoritic impact events. In the latter sediment is highly varied in its origins, composition, size and physical properties. Its role as an accidental part of the Rock Cycle establishes sedimentology as a fundamental part of Earth System Science. Indeed, as one nice semi-popular review entitled it a decade ago (Stanley & Hardie, 1999), from the point-of-view of calcareous sediment, ‘Hypercalcification: Paleontology Links Plate Tectonics and Geochemistry to Sedimentology’. We shall examine such grand claims later in this book (Chapter 23).

It is traditional to divide rock weathering into physical and chemical components, but in reality the two are inextricably interlinked. Water is the chief reactant and plays a dual role since it also transports away both dissolved and solid weathering products. Earthispresentlyuniqueinits abundanceofwater and water vapour, yet Mars also had an earlier watery prehistory. It is easy to take water for granted, the deceptively simple molecule H₂O has remarkable properties of great importance for rock and mineral weathering (Cookie 1). These include its solvent and hydration properties, wetting effects due to high saturation and anomalous decreaseofdensityatlow liquid temperatures and after freezing. An outline of the near-surface terrestrial hydrological cycle is given in Fig. 1.1.

Chemical weathering involves aqueous reactions with a strong biochemical component since dissolved atmospheric gases are aided by soil-generated gases, dilute acids and organic ligands. Further, the reactions are complex since silicate minerals are involved, with their many constituent anions and cations; also the amount of water and dissolved ions varies in both time and space. Four main mechanisms contribute to chemical weathering: dissolution, oxidation, hydrolysis and acid hydrolysis. Reactions usually occur at mineral surfaces in the unsaturated (vadose) zone where, close to the local Earth’s surface, rock pores contain atmospheric gases, water, living and dead vegetation and bacteria—all play an important role in weathering. The result is a regolith and soil profile whose characteristics depend upon climate and rock type.

Physical weathering involves the application of differential stresses to rock and mineral discontinuities in the unsaturated zone. These cause fragmentation and are due to erosional unloading, gravity, wind shear, salt crystallization from groundwaters, freeze–thaw and differential thermal expansion.

The combined effects of biochemical and physical weathering produce a weathered regolith profile in bedrock that comprises:

Interfaces between these layers are in a state of slow downward motion as the landscape reduces. In fact, landscape dating by cosmogenic isotopes and other means reveals that a steady-state system often exists, with the material mass removed by erosion being replaced by an equal volume made available from below for further decomposition.

Weathering acts on:

Weathering involves:

Weathering depends on: