Chesapeake Bay impact crater explained

Chesapeake Bay impact crater
Photo Size:250px
Map:USA Virginia
Map Size:250px
Location:Chesapeake Bay
Label:Impact location
Coordinates Ref:[1]
Confidence:Confirmed
Diameter:85km (53miles)
Depth:1.3km (00.8miles)
Imp Size:3km (02miles)
Age:35.5 ± 0.3 million
Exposed:No
Drilled:Yes
Bolide:L chondrite[2]
Language:English
Access:U.S. Route 13 to S.R. 184
Country:United States
State:Virginia
Municipality:Cape Charles

The Chesapeake Bay impact crater is a buried impact crater, located beneath the mouth of Chesapeake Bay, United States. It was formed by a bolide that struck the eastern shore of North America about 35.5 ± 0.3 million years ago, in the late Eocene epoch. It is one of the best-preserved "wet-target" impact craters in the world.[3]

Continued slumping of sediments over the rubble of the crater has helped shape the Chesapeake Bay.

Formation and aftermath

During the warm late Eocene, sea levels were high, and the tidewater region of Virginia lay in the coastal shallows. The shore of eastern North America, about where Richmond, Virginia is today, was covered with thick tropical rainforest, and the waters of the gently sloping continental shelf were rich with marine life that was depositing dense layers of lime from their microscopic shells.

The bolide made impact at a speed of approximately 17.8abbr=offNaNabbr=off,[4] punching a deep hole through the sediments and into the granite continental basement rock. The bolide itself was completely vaporized, with the basement rock being fractured to depths of 8abbr=on0abbr=on, and a peak ring being raised around it. The deep crater, 38km (24miles) across, is surrounded by a flat-floored terrace-like ring trough with an outer edge of collapsed blocks forming ring faults.

The entire circular crater is about 85km (53miles) in diameter and 1.3abbr=onNaNabbr=on deep, an area twice the size of Rhode Island, and nearly as deep as the Grand Canyon. However, numerical modeling techniques by Collins et al. indicate that the post-impact diameter was likely to have been around 40km (30miles), rather than the observed 85km (53miles).

The surrounding region suffered massive devastation. USGS scientist David Powars, one of the impact crater's discoverers, described the immediate aftermath: "Within minutes, millions of tons of water, sediment, and shattered rock were cast high into the atmosphere for hundreds of miles along the East Coast." An enormous megatsunami engulfed the land and possibly even reached the Blue Ridge Mountains.[5] The sedimentary walls of the crater progressively slumped in, widened the crater, and formed a layer of huge blocks on the floor of the ring-like trough. The slump blocks were then covered with the rubble or breccia. The entire bolide event, from initial impact to the termination of breccia deposition, lasted only a few hours or days. In the perspective of geological time, the 1.2lk=onNaNlk=on breccia was an instantaneous deposit. The crater was then buried by additional sedimentary beds that have accumulated during the 35 million years following the impact.

The impact has been identified as the source of the North American tektite field, namely the Georgiaite and Bediasite fields.[6]

Discovery

Until 1983 there was no evidence of a large impact crater buried beneath the lower part of the Chesapeake Bay and its surrounding peninsulas. The first hint was a 20cm (10inches) layer of ejecta found in a drilling core taken off Atlantic City, New Jersey, about 1700NaN0 to the north. The layer contained the fused glass beads called tektites and shocked quartz grains that are unmistakable signs of a bolide impact.

In 1993, data from oil exploration revealed the extent of the crater.[7]

Effects on local rivers

The continual slumping of the rubble within the crater has affected the flow of the rivers and shaped the Chesapeake Bay. The impact crater created a long-lasting topographic depression which helped predetermine the course of local rivers and the eventual location of the Chesapeake Bay. Most important for present-day inhabitants of the area, the impact disrupted aquifers. The present freshwater aquifers lie above a deep salty brine, remnants of 100- to 145-million-year-old Early Cretaceous North Atlantic seawater, making the entire lower Chesapeake Bay area susceptible to groundwater contamination.[8]

See also

Bibliography

External links

Notes and References

  1. Chesapeake Bay . 15 September 2019 . ChesapeakeBay . html.
  2. Schmitz. Birger. Boschi. Samuele. Cronholm. Anders. Heck. Philipp R.. Monechi. Simonetta. Montanari. Alessandro. Terfelt. Fredrik. Fragments of Late Eocene Earth-impacting asteroids linked to disturbance of asteroid belt. Earth and Planetary Science Letters. 425. 2015. 77–83. 0012-821X. 10.1016/j.epsl.2015.05.041. 2015E&PSL.425...77S. free.
  3. Web site: Chesapeake Bay impact structure: Morphology, crater fill, and relevance for impact structures on Mars. USGS. United States Geological Survey. 5 March 2019. 2006.
  4. Collins. Gareth S.. Wünnemann. Kai. How big was the Chesapeake Bay impact? Insight from numerical modeling. Geology. 2005. 33. 12. 925–928. 10.1130/G21854.1. 2005Geo....33..925C.
  5. Web site: Dell'Amore. Christine. "Mind-Blowing" Discovery: Oldest Body of Seawater Found in Giant Crater. https://web.archive.org/web/20131121133537/http://news.nationalgeographic.com/news/2013/11/131120-oldest-seawater-chesapeake-bay-crater-science/. dead. 2013-11-21. National Geographic. National Geographic Society. 2015-07-01. 2013-11-21.
  6. Koeberl. C.. Poag. C. W.. Reimold. W. U.. Brandt. D.. Impact Origin of the Chesapeake Bay Structure and the Source of the North American Tektites. Science. 1996-03-01. 271. 5253. 1263–1266. 10.1126/science.271.5253.1263. 1996Sci...271.1263K. 128672140.
  7. Book: Poag. C. Wylie. Koeberl. Christian. Reimold. Wolf Uwe. The Chesapeake Bay crater: geology and geophysics of a Late Eocene submarine impact structure. 1 January 2004. 69–93. 10.1007/978-3-642-18900-5. 7 October 2016. Springer-Verlag. Berlin, Germany. Impact Studies. 978-3-642-62347-9. 9 October 2016. https://web.archive.org/web/20161009185514/https://pubs.er.usgs.gov/publication/70121562. dead.
  8. Sanford. Ward E.. Doughten. Michael W.. Coplen. Tyler B.. Hunt. Andrew G.. Bullen. Thomas D.. Evidence for high salinity of Early Cretaceous sea water from the Chesapeake Bay crater. Nature. 13 November 2013. 503. 7475. 252–256. 10.1038/nature12714. 24226889. 2013Natur.503..252S. 1735841.