There are four different perspectives needed to classify passive margins: • map-view formation geometry (rifted, sheared, and transtensional), • nature of transitional crust (volcanic and non-volcanic), • whether the transitional crust represents a continuous change from normal continental to normal oceanic crust or this includes isolated rifts and stranded continental blocks (simple and complex), and • sedimentation (carbonate-dominated, clastic-dominated, or sediment starved). The first describes the relationship between rift orientation and plate motion, the second describes the nature of transitional crust, and the third describes post-rift sedimentation. All three perspectives need to be considered in describing a passive margin. In fact, passive margins are extremely long, and vary along their length in rift geometry, nature of transitional crust, and sediment supply; it is more appropriate to subdivide individual passive margins into segments on this basis and apply the threefold classification to each segment.
Geometry of passive margins Rifted margin This is the typical way that passive margins form, as separated continental tracts move perpendicular to the coastline. This is how the Central
Atlantic opened, beginning in
Jurassic time. Faulting tends to be
listric:
normal faults that flatten with depth.
Sheared margin Sheared margins form where continental breakup was associated with
strike-slip faulting. A good example of this type of margin is found on the south-facing coast of west Africa. Sheared margins are highly complex and tend to be rather narrow. They also differ from rifted passive margins in structural style and thermal evolution during continental breakup. As the
seafloor spreading axis moves along the margin, thermal uplift produces a ridge. This ridge traps sediments, thus allowing for thick sequences to accumulate. These types of passive margins are less volcanic.
Transtensional margin This type of passive margin develops where rifting is oblique to the coastline, as is now occurring in the
Gulf of California.
Nature of transitional crust Transitional crust, separating true oceanic and continental crusts, is the foundation of any passive margin. This forms during the rifting stage and consists of two endmembers: volcanic and non-volcanic. This classification scheme only applies to rifted and transtensional margin; transitional crust of sheared margins is very poorly known.
Non-volcanic rifted margin Non-volcanic margins are formed when extension is accompanied by little
mantle melting and volcanism. Non-volcanic transitional crust consists of stretched and thinned continental crust. Non-volcanic margins are typically characterized by continentward-dipping seismic reflectors (rotated crustal blocks and associated sediments) and low P wave velocities (p=7.1-7.8 km/s) – referred to as lower crustal bodies (LCBs) in the geologic literature The high velocities (Vp > 7 km) and large thicknesses of the LCBs are evidence that supports the case for plume-fed accretion (mafic thickening) underplating the crust during continental breakup. LCBs are located along the continent-ocean transition but can sometimes extend beneath the continental part of the rifted margin (as observed in the mid-Norwegian margin for example). In the continental domain, there are still open discussion on their real nature, chronology, geodynamic and petroleum implications. Examples of volcanic margins: • The Yemen margin • The East Australian margin • The West Indian margin • The Hatton-Rockal margin • The U.S. East Coast • The mid-Norwegian margin • The Brazilian margins • The Namibian margin • The East Greenland margin • The West Greenland margin Examples of non-volcanic margins: • The Newfoundland Margin • The Iberian Margin • The Margins of the Labrador Sea (Labrador and Southwest Greenland)
Heterogeneity of transitional crust Simple transitional crust Passive margins of this type show a simple progression through the transitional crust, from normal continental to normal oceanic crusts. The passive margin offshore
Texas is a good example.
Complex transitional crust This type of transitional crust is characterized by abandoned
rifts and continental blocks, such as the
Blake Plateau,
Grand Banks, or
Bahama Islands offshore eastern Florida.
Sedimentation A fourth way to classify passive margins is according to the nature of
sedimentation of the mature passive margin. Sedimentation continues throughout the life of a passive margin. Sedimentation changes rapidly and progressively during the initial stages of passive margin formation because rifting begins on land, becoming marine as the rift opens and a true passive margin is established. Consequently, the sedimentation history of a passive margin begins with fluvial, lacustrine, or other subaerial deposits, evolving with time depending on how the rifting occurred and how, when, and by what type of sediment it varies.
Constructional Constructional margins are the "classic" mode of passive margin sedimentation. Normal sedimentation results from the
transport and
deposition of sand, silt, and clay by
rivers via
deltas and redistribution of these sediments by
longshore currents. The nature of sediments can change remarkably along a passive margin, due to interactions between carbonate sediment production, clastic input from rivers, and alongshore transport. Where
clastic sediment inputs are small,
biogenic sedimentation can dominate especially nearshore sedimentation. The
Gulf of Mexico passive margin along the southern United States is an excellent example of this, with muddy and sandy coastal environments down current (west) from the
Mississippi River Delta and beaches of
carbonate sand to the east. The thick layers of sediment gradually thin with increasing distance offshore, depending on subsidence of the passive margin and the efficacy of offshore transport mechanisms such as
turbidity currents and
submarine channels. Development of the shelf edge and its migration through time is critical to the development of a passive margin. The location of the shelf edge break reflects complex interaction between sedimentation, sealevel, and the presence of sediment dams. Coral reefs serve as bulwarks that allow sediment to accumulate between them and the shore, cutting off sediment supply to deeper water. Another type of sediment dam results from the presence of
salt domes, as are common along the
Texas and
Louisiana passive margin.
Starved Sediment-starved margins produce narrow continental shelves and passive margins. This is especially common in arid regions, where there is little transport of sediment by rivers or redistribution by longshore currents. The Red Sea is a good example of a sediment-starved passive margin. ==Formation==