Accommodation was defined by Jervey (1998) as "the space available for potential sediment accumulation. This space is the combined product of movement of:
Helland-Hansen and Martinsen (1960) consider the processes responsible for the slope of the
trajectory taken by these
retrogradational,
aggradational and
progradational
parasequences of a
shoreline. They suggest that this is controlled by the character of the
accommodation and its interaction with the flux of sediment into these marine settings. this flux is reflected in transportion via the
shoreline (the maximum wave energy zone) and redistribution in response to the hydrodynamic regime of the
basin. Pomar and Kendall (2009) describe how sediments aggrade till waves and currents move them down-shelf, flattening of the depositional profile. These profiles are not only associated with the original
accommodation as it relates to the slope but a
basinward grain-size decrease that reflects the balance between input, redistribution and
accumulation of sediment (Johnson, 1919; Reineck and Singh, 1980; Allen, 1982; Swift et al. 1991b). The resulting "physical"
accommodation is modified by this "shelf equilibrium profile" of Swift and Thorne (1991). This profile of Swift and Thorne (1991) represents a conceptual surface of dynamic equilibrium similar to the "marine profile of equilibrium" of Dietz (1963). It is an expression of the notion of wave-base matching the greatest depth to which the bottom is stirred by waves during storms (Rich, 1951).
Thus "physical"
accommodation comprises the space between sea floor and the "shelf equilibrium profile" of Swift and Thorne (1991), and the
undaform,
clinoform and
fondoforms of Rich (1951). In fact the "
base level" for sediment
accumulation tends to match the "shelf equilibrium profile" and is often confused with sea level. This should be no surprise since base-level datum will be effectively equivalent to sea level when associated with overfed sedimentary systems like deltas. Conversely the "dynamic equilibrium" between sediment input and hydrodynamic power mean that deepening of the shelf equilibrium profile (delta retreat) will result if there is a subsequent decrease in sediment supply.
In conclusion
eustasy and total sea-floor subsidence, as well as changes in hydrodynamic conditions, govern many of the changes of
accommodation space. It should be recognized that unlike the
accommodation of siliciclastics descri
bed above, the
accommodation space for
carbonates, is affected by hydrodynamics, but also the capacity of organisms to produce and to accumulate sediments above certain hydrodynamic thresholds. This later effect is the
ecological accommodation defined by Pomar (2001 a and b).
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