Geological shoulder

In geology, a geological shoulder or rift shoulder is an area of uplifted terrain resulting from the compensatory movement of large-scale tectonic processes. These features are distinct from reliefs caused by compressional tectonics, as they arise from extensional forces rather than compression.^[1]

Geological shoulder

Rift shoulders are significant topographic features, often reaching elevations of several kilometers, that form mountainous belts along the edges of central rift depressions. The origin of these shoulders has been the subject of extensive research since the 1980s.^[1] The isostatic compensation model proposed by Felix Andries Vening Meinesz in 1950, also known as the isostatic or flexural rebound model, explains the permanent topographic uplift that occurs during rifting and persists on passive margins despite erosion.^[2] This model is complemented by additional theories that account for factors such as creep, mantle magma underplating, or dynamic support. These explore the influence of rheological parameters, extension rates, crustal thickness, and fault geometry in greater detail.^[3]

Examples

Examples of geological shoulders are:

Geological shoulders of the East African Rift;^[3]
Margins of the Red Sea;^[4]
Cantabrian Mountains and Armorican Massif, forming the shoulders of the Bay of Biscay;^[4]
Passive margins of the Atlantic Ocean: northern eastern Greenland and western Scandinavia;^[3]
Passive margins of the Mascarene Basin (resulting from Indo-Madagascan rifting): eastern Madagascar and western India.^[4]

These examples highlight the global distribution of geological shoulders and their association with major tectonic features.^[4]

References

^ ^a ^b Ruppel, Carolyn (10 December 1995). "Extensional processes in continental lithosphere". Journal of Geophysical Research: Solid Earth. 100 (B12): 24187–24215. Bibcode:1995JGR...10024187R. doi:10.1029/95JB02955.
^ Vening-Meinesz, F.A. (1950). "Les grabens africains, résultat de compression ou de tension dans la croûte terrestre" [African grabens, the result of compression or tension in the Earth's crust]. Bulletin de l'Institut Royal Colonial Belge (21): 539–552.
^ ^a ^b ^c Deverchere, Jacques (1999). "Rifting continental : Causes, effets, évolution - Exemple du rift Baïkal" [Continental rifting: Causes, effects, evolution - Example of the Baikal Rift] (PDF). Tectonique, Université Paris 6 - Pierre et Marie Curie. p. 20. Retrieved 5 May 2025.
^ ^a ^b ^c ^d Braun, J.; Beaumont, C. (1989). "A physical explanation of the relation between flank uplifts and the breakup unconformity at rifted continental margins". Geology. 17 (8): 760–764. Bibcode:1989Geo....17..760B. doi:10.1130/0091-7613(1989)017<0760:APEOTR>2.3.CO;2.

[:0-1] Ruppel, Carolyn (10 December 1995). "Extensional processes in continental lithosphere". Journal of Geophysical Research: Solid Earth. 100 (B12): 24187–24215. Bibcode:1995JGR...10024187R. doi:10.1029/95JB02955.

[2] Vening-Meinesz, F.A. (1950). "Les grabens africains, résultat de compression ou de tension dans la croûte terrestre" [African grabens, the result of compression or tension in the Earth's crust]. Bulletin de l'Institut Royal Colonial Belge (21): 539–552.

[:2-3] Deverchere, Jacques (1999). "Rifting continental : Causes, effets, évolution - Exemple du rift Baïkal" [Continental rifting: Causes, effects, evolution - Example of the Baikal Rift] (PDF). Tectonique, Université Paris 6 - Pierre et Marie Curie. p. 20. Retrieved 5 May 2025.

[:1-4] Braun, J.; Beaumont, C. (1989). "A physical explanation of the relation between flank uplifts and the breakup unconformity at rifted continental margins". Geology. 17 (8): 760–764. Bibcode:1989Geo....17..760B. doi:10.1130/0091-7613(1989)017<0760:APEOTR>2.3.CO;2.