TY - JOUR
T1 - Interplay of autogenic and allogenic processes on the formation of shallow carbonate cycles in a synrift setting (Lower Pliensbachian, Traras Mountains, NW Algeria)
AU - Belkhedim, Salim
AU - Jarochowska, Emilia
AU - Benhamou, Miloud
AU - Nemra, Abdelkrim
AU - Sadji, Radouane
AU - Munnecke, Axel
N1 - Funding Information:
This study is a part the Ph.D. thesis of S. Belkhedim, funded by the Algerian Ministry of Higher Education and Scientific Research. The authors would like to thank Morad Rebba, Mohamed Aimouche, Lakhdar Boudia, and Mourad Kecili (Oran, Algeria) for their support during field work. We are very grateful to Birgit Leipner-Mata (Erlangen) for preparation of the high-quality thin sections. We are also grateful to Dan Bosence, an anonymous reviewer, and Associate Editor Peter Burgess (Liverpool, UK) for their constructive comments that significantly improved the quality of this paper. Specific thanks go to Corresponding Editor John Southard and to Carl J. Reddin (Erlangen) for checking the English.
Publisher Copyright:
© 2019, SEPM (Society for Sedimentary Geology) 1527-1404/19/089-784
PY - 2019
Y1 - 2019
N2 - Meter-scale shallowing-upward cycles are recorded in many carbonate successions around the world. It is often difficult to recognize whether they represent autocycles, formed through intrinsic controls, or allocycles, resulting from orbital forcing or tectonic movements, or both. Here, we review the criteria used in the identification of the two types of cyclicity and apply them to two newly described lower Pliensbachian outcrops in the Traras Mountains, northwestern Algeria. Throughout the investigation of six sections, the deposits are suggested to have formed in intertidal-supratidal to shallow subtidal environments on a tropical ramp in the Western Tethys. In this area, shallowing-upward small-scale peritidal and subtidal cycles have been shown to be, and are assumed to be, ordered. The carbon isotope data mirror the recorded cycles and indicate different lengths of subaerial exposures. These cycles, in a developed within synrift setting, have been interpreted as produced mainly by autocyclic processes, but interacting with allocyclic factors. Peritidal cycles are thought to be generated by progradation of intertidal and supratidal flats into lagoonal sediments, while subtidal cycles are interpreted to have been controlled by lateral migration of shoals. The impact of the minor fluctuations of eustatic sea level is weakly marked, and only long subaerial exposure can reveal the contribution of these fluctuations to the formation of the recorded cycles. Tectonic movements resulting from spreading of the Tethys are interpreted to have controlled cycle distribution and thickness at a regional scale. However, synsedimentary tectonic features are rare in the studied area; this suggests that sediment transport would control the thickness and duration of cycles instead of the rate at which accommodation was created.
AB - Meter-scale shallowing-upward cycles are recorded in many carbonate successions around the world. It is often difficult to recognize whether they represent autocycles, formed through intrinsic controls, or allocycles, resulting from orbital forcing or tectonic movements, or both. Here, we review the criteria used in the identification of the two types of cyclicity and apply them to two newly described lower Pliensbachian outcrops in the Traras Mountains, northwestern Algeria. Throughout the investigation of six sections, the deposits are suggested to have formed in intertidal-supratidal to shallow subtidal environments on a tropical ramp in the Western Tethys. In this area, shallowing-upward small-scale peritidal and subtidal cycles have been shown to be, and are assumed to be, ordered. The carbon isotope data mirror the recorded cycles and indicate different lengths of subaerial exposures. These cycles, in a developed within synrift setting, have been interpreted as produced mainly by autocyclic processes, but interacting with allocyclic factors. Peritidal cycles are thought to be generated by progradation of intertidal and supratidal flats into lagoonal sediments, while subtidal cycles are interpreted to have been controlled by lateral migration of shoals. The impact of the minor fluctuations of eustatic sea level is weakly marked, and only long subaerial exposure can reveal the contribution of these fluctuations to the formation of the recorded cycles. Tectonic movements resulting from spreading of the Tethys are interpreted to have controlled cycle distribution and thickness at a regional scale. However, synsedimentary tectonic features are rare in the studied area; this suggests that sediment transport would control the thickness and duration of cycles instead of the rate at which accommodation was created.
UR - http://www.scopus.com/inward/record.url?scp=85072404192&partnerID=8YFLogxK
U2 - 10.2110/jsr.2019.33
DO - 10.2110/jsr.2019.33
M3 - Article
AN - SCOPUS:85072404192
SN - 1527-1404
VL - 89
SP - 784
EP - 807
JO - Journal of Sedimentary Research
JF - Journal of Sedimentary Research
IS - 8
ER -