بهبهانی، ر.، محسنی، ح.، خدابخش، س.، آتش­مرد، ز (1390) شواهد رسوبات توفانی و توربیدایتی در سازند پابده، شمال و جنوب باختر حوضه زاگرس. پژوهش­های چینه­نگاری و رسوب­شناسی، شماره 42، ص 73-96.

سراوانی، س.، گرگیج، م. ن.، قماشی، م.، احمدی، ع (1396) تجزیه و تحلیل ریز­رخساره­ای، محیط­های رسـوبی و چینه­نگاری سکانسی سازند پابده در برش نمونه، زاگرس. پژوهش­های چینه­نگاری و رسوب­شناسی، شماره 69، ص 69-104.

غلامی­زاده، پ.، آدابی، م. ح.، حسینی­برزی، م.، صادقی، ع.، قاسمی، م. ر (1395) بازسازی محیط رسوبی نهشته­های آواری میوسن حوضه رسوبی زاگرس در برش­های کوه آسکی و هورگان، گستره نیریز، حوضه زاگرس. فصل­نامه علوم زمین، شماره 101، ص 23-34.

محسنی، ح.، جوانمرد، ر. ا (1397) ریزرخساره­ها و محیط رسوبی سازند سروک در برش تنگ باولک و شاهنخجیر، شهرستان ملک­شاهی (ایلام). پژوهش­های چینه­نگاری و رسوب­شناسی، شماره 71، ص 43-68.

محسنی، ح.، طولابی، م.، یوسفی­یگانه، ب.، خدابخش، س (1392) شواهد رسوبی جریان توربیدایتی در سازند امیران در جنوب باختر لرستان. هفدهمین همایش انـجمن زمین­شناسی ایران، دانشگاه شهید بهشتی، 9 ص.

نصیری، ی.، محبوبی، ا.، موسوی حرمی، ر.، خزایی، ا. ر.، یوسفی­یگانه، ب (1392) بازسازی محیط رسوبی رسوبات سیلیسی آواری-کربناته سازند امیران (کرتاسه بالایی-پالئوسن) در جنوب­باختر لرستان. فصل­نامه زمین­شناسی ایران، شماره 27، ص 55-74.

Abdi, A., Mahmudi-Gharaie, M. H., Badenas, B (2014) Internal wave deposits in Jurassic Kermanshah pelagic carbonates and radiolarites (Kermanshah area, West Iran). Sedimentary Geology, 314: 47-59.

Allen, P. A (1997) Earth surface processes. Blackwell, London, 404 pp.

Alvarez, M. I. D. P., Alonso, J. L., Fernandez, L. P (2019) Gravity driven structures and deposits resulting from slope collapse in the margin of a carbonate platform (NW Iberia). Journal of Structural Geology, 119: 15-32.

Baas, J. H (2004) Conditions for formation of massive turbiditic sandstones by primary depositional processes. Sedimentary Geology, 166: 293-310.

Baas, J. H., Best, J. L (2002) Turbulence modulation in clay-rich sediment laden flows and some implications for sediment deposition. Journal of Sedimentary Research, 72: 336-340.

Berra, F (2007) Sedimentation in shallow to deep water carbonate environmens across a sequence boundary: effects of a fill in sea-level on the evolution of a carbonate system (Ladinian-Carrnian, eastern Lombardy, Italy). Sedimentology, 54: 721-735.

Betzler, C., Brachert, T. C., Kroon, D (1995) Role of climate in partial drowning of the Queensland plateau carbonate platform (northeastern Australia). Marine Geology, 123: 11-32.

Bouma, A. H (1962) Sedimentology of some flysch deposits: a graphic approach to facies interpretation, Elsevier, Amsterdam, 168 pp.

Bouma, A. H (2000) Fine-grained, mud-rich turbidite systems: model and comparison with coarse-grained, sand-rich systems. In: Bouma, A. H., Stone, C. G (eds.), Fine-grained turbidite systems. AAPG Memoir 72/SEPM Special Publication 68, p. 9-19.

Bouma, A. H., Normark, W. R., Barnes, N. E (1985) Submarine fans and related turbidite systems. Springer-Verlag, New York, 351 pp.

Bouma, A. H., Stone, (eds.) (2000) Fine-grained turbidite system. American Association of Petroleum Geologists, Memoir 72, 342 pp.

Bromley, R. G (1990) Trace fossils: biology and taphonomy. Academic Division of Unwin Hyman Ltd., Boston, 280 pp.

Burg, J. P., Dolati, A., Bernoulli, D., Smit, J (2012) Structural style of the Makran Tertiary accretionary complex in SE Iran. In: Al-Hosani, K., Roure, F., Ellison, R., Lokier, S., (eds.), Lithosphere dynamics and sedimentary basins: the Arabian Plate and analogues. Springer-Verlag, Heidelberg, p. 239-259.

Cantalejo, B., Pickering, K. T (2014) Climate forcing of fine grained deep-marine system in an active tectonic setting: Middle Eocene, Ainsa Basin, Spanish Pyrenees. Palaeo, 410: 351-371.

Coniglio, M., Dix, G. R (1992) Carbonate slopes. In: Walker, R. G., James, N. P., (eds.), Facies models: response to sea level change. Geological Association of Canada, p. 349-374.

Corella, J. P., Loizeau, J. L., Kremer, K., Hilb, M. and et al (2016) The role of mass-transport deposits and turbidites in shaping modern lacustrine deepwater channels, Marine and Petroleum Geology, 77: 515-525.

Dolati, A (2010) Stratigraphy, structural geology and low-temperature thermochronology across the Makran accretionary wedge in Iran. PHD thesis, Swiss Institute of Technology, Zurich, 311 pp.

Dott, R. H (1963) Dynamics of subaqueous gravity depositional processes. American Association of Petroleum Geologists, Bulletin, 47: 104-128.

Eberli, G. P (1987) Calcareous turbidites and their relationship to sea-level fluctuations and tectonism. In: Einsele, G., Ricken, W., Seilacher, A., 1991, (eds.), Cycles and events in stratigraphy. Springer-Verlag, Berlin, p. 340-359.

Everts, A. J. W (1991) Interpreting compositional variations of calciturbidites in relation to platform stratigraphy: an example from the paleogene of SE Spain. Sedimentary Geology, 71: 231-242.

Everts, A. J. W., Schalger, W., Reijmer, J. J. G (1999) Carbonate platform to basin correlation by means of grain composaition logs: an example from thr Vercors (Cretaceous, SE France). Sedimentology, 46: 261-278.

Fan, A., Yang, R., Van-Loon, A. J., Yin, W., Han, Z., Zavala, C (2018) Classification of gravity-flow deposits and their sinsignificancer unconventional petroleum exploration, with a case study from the Triassic Yanchang Formation (China). Journal of Asian Earth Sciences, 161: 57-73.

Floquet, M., Hennuy, J (2003) Evolutionary gravity flow deposits in the Middle Turonian-Early Coniacin Southern Provence Basin (SE France): Origins and depositional processes. In: Locat, J., Mienert, J. (eds.), submarine mass movements and their consequences 19. Kluwer Academic Publishers, Dordrecht, the Netherlands, p. 417-424.

Flugel, E (2010) Microfacies of carbonate rocks: analysis, interpretation and application (2^nd edition). Springer-Verlag, Berlin, Heidelberg, 984 pp.

Gani, M. R (2003) Crisis for a general term referring to all types of sediment gravity flow deposits: grevite. Geological Society of America, Abstracts with Programs, 34: 171.

Gani, M. R (2004) From turbid to lucid: a straightforward approach to sediment gravity flows and their deposits. The Sedimentary Record, 2: 4-8.

Gladstone, C., Phillips, J. C., Sparks, R. S. J (1998) Expriments on bidisperse, constant-volume gravity currents: propagation and sediment deposition. Sedimentology, 45: 833-843.

Groen, R. D (2008) Origin of tectonically induced calcite debris flows (Cretaceous, Southern Provence Basin, France). (Bachlor thesis) VU University Amsterdam, Amsterdam, 33 pp.

Hampton, M. A (1975) Competence of fine-grained debris flows. Journal of sedimentary Petrology, 45: 834-844.

Horikawa, K., Ito, M (2009) Non-uniform across-shelf variations in thickness, grain size, and frequency of turbidites in a transgressive outer-shelf, the Middle Pleistocene Kakinokidai Formation, Boso Peninsula, Japan. Sedimentary Geology, 220: 105-115.

Ito, M (2019) Lithofacies architecture of gravel-wave deposits: insights into the origins of coarse-grained gravity-flow deposits. Sedimentary Geology, 382: 35-46.

Kneller, B. C., and Branney, M. J (1995) Sustained high-density turbidity currents and the deposition of thick massive sands. Sedimentology, 42: 231-258.

Liu, F., and et al (2015) Sedimentary characteristics and facies model of gravity flow deposits of Late Triassic Yan-Chang Formation in Southwest in Ordos Basin, NW China. Petroleum Exploration and Development, 42: 633-645.

Lowe, D. R (1982) Sediment gravity flows, II. Depositional models with special reference to the deposits of high-density turbidity currents. Journal of Sedimentary Petrology, 52: 279-297.

Lowe, D. R., Guy, M (2000) Slurry-flows deposits in the Britanian Formation (Lower Cretaceous), North Sea: a new perspective on the turbidity current and debris flow problem. Sedimentology, 47: 31-70.

Miall, A. D (2006) The geology of fluvial deposits: sedimentary facies, basin analysis, and petroleum geology (4^th edition). Springer, Berlin, 582 pp.

Middleton, G. V., Hampton, M. A (1973) Sediment gravity flows: mechanics of flow and deposition. In: Middleton, G. V., Bouma, A. H., (eds.), Turbidites and deep water sedimentation. Proceedings of Pacific Section Society of Economic Paleontologists and Mineralogists, Los Angeles, p. 1-38.

Mohammadi, A., Burg, J. P., Bouilhol, P., Ruh, J (2016) U-Pb geochronology and geochemistry of Zahedan and Shah-Kuh plutons, southeast Iran: implication for closure South Sistan suture zone. Lithos, 248 (251): 293-308.

Mohseni, H., Behbahani, R., Khodabakhsh, S., Atashmard, Z (2011) Depositional rnvironments and trace fossil assemblages in the Pabdeh Formation (Paleogene), Zagros Basin, Iran. N. Jb. Geol. Palaont. Abh, 262: 59-77.

Mulder, T., Syvitski, J. P. M., Migeon, S., Faugeres, J. C., Savoye, B (2003) Marine hyperpycnal flows: initiation, behavior and related deposits, a review. Marine and Petroleum Geology, 20: 861-882.

Mutti, E (1992) Turbidite sandstones. Special Publication, Agip, Milan, 275 pp.

Mutti, E., Normark, W. R (1991) An integrated approach to the study of turbidite systems. In: Weimer, P., Link, M. H., (eds.), Seismic facies and sedimentary processes of submarine fans and turbidite systems. Springer-Verlag, New York, p. 75-106.

Nichols, G (2009) Sedimentology and stratigraphy (2^nd edition). Chichester, UK; Blackwell Science, 432 pp.

Payros, A., Pujalt, v (2001) Calciclastic submarine fans: an integrated overview. Earth Science Reviews, 86: 203-246.

Pickering, K. T., Corregidor, J (2005) Mass-transport complexes and tectonic control on basin floor submarine fans, Middle Eocene, South Spanish Pyrenees. Journal of Sedimentary Research, 75: 761-783.

Quiquerez, A., Sarih, S., Allemand, P., Garcia, J. P (2013) Fault rate controls on carbonate gravity-flow deposits of the Liassic of central High Atlas (Morocco). Marine and Petroleum Geology, 43: 349-369.

Ragusa, J., Kindler, P (2018) Compositional variations in deep-sea gravity flow deposits. A case study from the Voirons Flysch (France). Sedimentary Geology, 377: 111-130.

Reading, H. G., Richards, M (1994) turbidite systems in deep water basin margins classified by grain size and feeder system. AAPG Bulletin, 78: 792-822.

Reijmer, J. J. G (1998) Compositional variations during phases of progradation and retrogradation of a Triassic carbonate platform (Picco di Vallandro/Durrenstein, Dolomites, Italy). Geoloische Rundschau, 87: 436-448.

Reijmer, J. J. G., Palmieri, P., Groen, R (2012) Compositional variations in calciturbidites and calcidebrites in response to sea level fluctuations (Exuma Sound, Bahamas). Facies, 58 (4): 493-507.

Reijmer, J. J. G., Pamieri, P., Groen, R., Floquet, M (2014) Calciturbidites and calcidebrrites: Sea-level variations or tectonic processes?. Sedimentary Geology, 317: 53-70.

Reijmer, J. J. G., Schalger, W., Bosscher, H., Beets, C. J., Mc Neill, D. F (1992) Pliocene/Pleistocene platform facies transition recorded in calciturbidites (Exuma Sound, Bahamas). Sedimentary Geology, 78: 171-179.

Rubert, Y., Jati, M., Loisy, C., Cerepi, A., Foto, G., Muska, K (2012) Sedimentology of resedimented carbonates: facies and geometrical charaterisation of an upper Cretaceous calciturbidite system in Albania. Sedimentary Geology, 257 (260): 63-77.

Sanders, J. E (1965) Primary sedimentary structures formed by turbidity currents and related resedimentation mechanisms, In: Middleton, G. V., (eds.), Primary sedimentary structures and their hydrodynamic interpretation. Society of Economic Paleontologists and Mineralogists Special Publication, 12: 192-219.

Savary, B., Ferry, S (2004) Geometry and petrophysical parameters of a calcarenitic turbidite lobe (barremian-Aptian, Pas-de-La-Cluse, France), Sedimentary Geology, 168: 281-304.

Shanmugam, G (1996) High–density turbidity currents: are they sandy debris flows? Journal of Sedimentary Research, 66: 2-10.

Shanmugam, G (1997) The bouma sequence and the turbidite mind set. Earth Science Reviews, 42: 201-229.

Shanmugam, G (2012) Bottom-current reworked sands. In: Shanmugam, G., (eds.), new perspectives on deep-water sandstones: origin, recognition, initiation, and reservoir quality. Elsevier, Amsterdam, p.129-219.

Stelting, Ch. E., Bouma, A. H., Stone, Ch. G (2000) Fine-grained turbidite systems: overview. In: Bouma, A. H., Stone, C. G (eds.), Fine-grained turbidite systems. AAPG Memoir 72/SEPM Special Publication, 68: 1-8.

Tinterri, R., Drago, M., Consonni, A., Davoli, G., Mutti, E (2003) Modeling subaqueous bipartite sediment gravity flows on the basis of outcrop constraints: first results. Marine and Petroleum Geology, 20: 911-933.

Tucker, M. E (1994) Sedimentary Petrology (2^nd edition). Blackwell, 272 pp.

Williams, G. P (1967) Flume experiments on the transport of a coarse sand: sediment transport in alluvial channels. Geological Survey Professional Paper 562-B, United States Government Printing Office, Washington, 31 pp.

Yang, P., et al (2017) Lithofacies and origin of the Late Triassic muddy gravity-flow deposits in the Ordos Basin, Central China. Marine and Petroleum Geology, 85: 194-219.

Zavala, C., Arcuri, M (2016) Intrabasinal and extrabasinal turbidites: origin and distinctive characteristics. Sedimentary Geology, 337: 36-54.