Tempestite

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Tempestite in Estonia (Silurian dolomite) Tempestite Estonian Silurian.jpg
Tempestite in Estonia (Silurian dolomite)

Tempestites are storm deposits that can be recognized throughout the geologic record. They are studied in the scientific disciplines of sedimentary geology and paleotempestology. The deposits derive their meaning from the word tempest, a violent storm. Tempestites are preserved within a multitude of sedimentary environments including delta systems, estuarian systems, coastal environments, deep sea environments, and fresh water lacustrine environments. Tempesites most often form in wave-dominated delta systems and preserve, within the sedimentary record, evidence of events and processes below fair weather wave base and above storm weather wave base. [1] They are commonly characterized by hummocky cross-stratified beds that have an erosive base, and can form under combined flow regimes. [2] This erosive base is often seen in the form of gutter casts.

Contents

Sequencing

Tempestites had been identified in the rock record for a long time, however the exact sequence of sedimentary structures that are commonly seen in the rock record, known as the idealized sequence, wasn't described until 1979 by Dott and Bourgeois. This idealized sequence follows the order of a hummocky cross stratified layer (H) often with sole markings on the base, followed by a planar laminated layer (F) synonymous to the lower place bed, followed by a cross laminated layer (X) preserved as ripple marks in plan view, and finally topped with a muddy layer (M) which is generally interpreted to be caused by suspensions settling of finer material during the waning period of the storm. Each one of these sedimentary structures can be affected by bioturbation, when organisms living in the sediment at the time burrow through it. Bioturbation, can be a great indicator of the depth of the water column the tempestite was deposited in, in a given study area, through the use if ichnology, as certain organisms will only persist at certain depths and will generate unique markings within the sedimentary structures that can be identified. However too much bioturbation can wipe out the preservation of the sedimentary structures and essentially making the bed massive, making the confident interpretation of a tempestite much more difficult for geologists. [2] Tempestites can also amalgamate due to their erosive bases and this will cause for portions of the idealized H-F-X-M sequence to repeat, as each storm event has eroded down into the sediment that was deposited by the last, and incorporating that sediment into its own deposit. [3]

Significance and Usage

Tempestite deposits are very useful for aiding in paleoecological and paleogeographica l interpretations. As storms that generate tempestite deposits can only form in between 5 degrees and 20 degrees north and south latitude (with even the largest 1000 year storm only being preserved upwards of 35 degrees latitude), accurate recognition of a tempestite deposit within the rock record allows for confident interpretation of a range of latitudes. Since hummocky cross stratification forms during the combined flow and waning oscillatory flow current regimes, the preserved amplitudes of their hummocks and swales are reflective of the storm intensity. Once it is understood where the deposit in question was deposited relative to the paleo-shoreline, which can usually be done using the ichnological data preserved in the same location, the hummock amplitudes/wavelengths, grainsize (decreases with increase in paleo water depth), and bedding thickness (decreases with increase in paleo water depth) can be used to estimate the storm intensity/energy. An understanding of the intensity of past storms has large implications for our understanding of how storm intensity might change with climate change occurring today. During the Cretaceous, CO2 levels were much higher and the global temperature was much higher. With an understanding of how storm intensity changed throughout this time period towards today, we can begin to understand how it will change with our changing climate. [4]

Tempestite deposits are also highly sought after petroleum reservoirs, as they are large laterally continuous sheet like deposits that have the potential to hold high volumes of petroleum with good permeability and porosity.

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Sedimentary rocks are types of rock that are formed by the accumulation or deposition of mineral or organic particles at Earth's surface, followed by cementation. Sedimentation is the collective name for processes that cause these particles to settle in place. The particles that form a sedimentary rock are called sediment, and may be composed of geological detritus (minerals) or biological detritus. The geological detritus originated from weathering and erosion of existing rocks, or from the solidification of molten lava blobs erupted by volcanoes. The geological detritus is transported to the place of deposition by water, wind, ice or mass movement, which are called agents of denudation. Biological detritus was formed by bodies and parts of dead aquatic organisms, as well as their fecal mass, suspended in water and slowly piling up on the floor of water bodies. Sedimentation may also occur as dissolved minerals precipitate from water solution.

<span class="mw-page-title-main">Unconformity</span> Rock surface indicating a gap in the geological record

An unconformity is a buried erosional or non-depositional surface separating two rock masses or strata of different ages, indicating that sediment deposition was not continuous. In general, the older layer was exposed to erosion for an interval of time before deposition of the younger layer, but the term is used to describe any break in the sedimentary geologic record. The significance of angular unconformity was shown by James Hutton, who found examples of Hutton's Unconformity at Jedburgh in 1787 and at Siccar Point in Berwickshire in 1788, both in Scotland.

<span class="mw-page-title-main">Varve</span> Annual layer of sediment or sedimentary rock

A varve is an annual layer of sediment or sedimentary rock.

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<span class="mw-page-title-main">Torridon Group</span>

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<span class="mw-page-title-main">Bouma sequence</span> Set of structures in sediments or sedimentary rocks

The Bouma sequence describes a classic set of sedimentary structures in turbidite beds deposited by turbidity currents at the bottoms of lakes, oceans and rivers.

<span class="mw-page-title-main">Carbonate platform</span> Sedimentary body with topographic relief composed of autochthonous calcareous deposits

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<span class="mw-page-title-main">Graded bedding</span> Type of layering in sediment or sedimentary rock

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<span class="mw-page-title-main">Bed (geology)</span> Layer of sediment, sedimentary rock, or pyroclastic material

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<span class="mw-page-title-main">Sedimentary structures</span> Geologic structures formed during sediment deposition

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<span class="mw-page-title-main">Hummocky cross-stratification</span>

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<span class="mw-page-title-main">Gai-As Formation</span>

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<span class="mw-page-title-main">Junggar Basin</span> Sedimentary basin in Xinjiang, China

The Junggar Basin, also known as the Dzungarian Basin or Zungarian Basin, is one of the largest sedimentary basins in Northwest China. It is located in Dzungaria in northern Xinjiang, and enclosed by the Tarbagatai Mountains of Kazakhstan in the northwest, the Altai Mountains of Mongolia in the northeast, and the Heavenly Mountains in the south. The geology of Junggar Basin mainly consists of sedimentary rocks underlain by igneous and metamorphic basement rocks. The basement of the basin was largely formed during the development of the Pangea supercontinent during complex tectonic events from Precambrian to late Paleozoic time. The basin developed as a series of foreland basins – in other words, basins developing immediately in front of growing mountain ranges – from Permian time to the Quaternary period. The basin's preserved sedimentary records show that the climate during the Mesozoic era was marked by a transition from humid to arid conditions as monsoonal climatic effects waned. The Junggar basin is rich in geological resources due to effects of volcanism and sedimentary deposition. According to Guinness World Records it is a land location remotest from open sea with great-circle distance of 2,648 km from the nearest open sea at 46°16′8″N86°40′2″E.

References

  1. Paul M. Myrow (1), John B. Southard (1996). "Tempestite Deposition". SEPM Journal of Sedimentary Research. 66. doi:10.1306/d426842d-2b26-11d7-8648000102c1865d. ISSN   1527-1404.{{cite journal}}: CS1 maint: numeric names: authors list (link)
  2. 1 2 Bourgeois, Joanne; Dott, R. H. (1982-08-01). "Hummocky stratification: Significance of its variable bedding sequences". GSA Bulletin. 93 (8): 663–680. Bibcode:1982GSAB...93..663D. doi:10.1130/0016-7606(1982)93<663:HSSOIV>2.0.CO;2. ISSN   0016-7606.
  3. Long, D Gf (2007-03-01). "Tempestite frequency curves: a key to Late Ordovician and Early Silurian subsidence, sea-level change, and orbital forcing in the Anticosti foreland basin, Quebec, Canada". Canadian Journal of Earth Sciences. 44 (3): 413–431. Bibcode:2007CaJES..44..413L. doi:10.1139/e06-099. ISSN   0008-4077.
  4. Li, Fengjie; Yang, Yuchuan; Li, Junwu; Yang, Chengjin; Dai, Tingyong; Zhao, Junxing; Yi, Haisheng (October 2014). "Lacustrine tempestite and its geological significance in the Cenozoic study of the Qaidam Basin". Journal of Asian Earth Sciences. 92: 157–167. Bibcode:2014JAESc..92..157L. doi:10.1016/j.jseaes.2014.06.020. ISSN   1367-9120.