Underwater archaeology

Last updated
Drawing to scale, underwater Scale drawing underwater.jpg
Drawing to scale, underwater
Rock house settlement seen on left in 1927 while Lake Murray (South Carolina) was under construction, middle and right are two angles of aspect on Side-scan sonar in 100 ft of fresh water under the lake in 2005 LakeMurray rockhouse overview.jpg
Rock house settlement seen on left in 1927 while Lake Murray (South Carolina) was under construction, middle and right are two angles of aspect on Side-scan sonar in 100 ft of fresh water under the lake in 2005
The wreck of E. Russ in Estonia is considered a national heritage monument. Kaubalaeva "E. Russ" vrakk.jpg
The wreck of E. Russ in Estonia is considered a national heritage monument.

Underwater archaeology is archaeology practiced underwater. [1] As with all other branches of archaeology, it evolved from its roots in pre-history and in the classical era to include sites from the historical and industrial eras.

Contents

Its acceptance has been a relatively late development due to the difficulties of accessing and working underwater sites, and because the application of archaeology to underwater sites initially emerged from the skills and tools developed by shipwreck salvagers. [2] As a result, underwater archaeology initially struggled to establish itself as actual archaeological research. [3] This changed when universities began teaching the subject and a theoretical and practical base for the sub-discipline was firmly established in the late 1980s.

Underwater archaeology now has a number of branches including, maritime archaeology: the scientifically based study of past human life, behaviors and cultures and their activities in, on, around and (lately) under the sea, estuaries and rivers. [4] This is most often effected using the physical remains found in, around or under salt or fresh water or buried beneath water-logged sediment. [5] In recent years, the study of submerged WWII sites and of submerged aircraft in the form of underwater aviation archaeology have also emerged as bona fide activity. [6]

Though often mistaken as such, underwater archaeology is not restricted to the study of shipwrecks. Changes in sea level because of local seismic events such as the earthquakes that devastated Port Royal and Alexandria or more widespread climatic changes on a continental scale mean that some sites of human occupation that were once on dry land are now submerged. [7] [8] At the end of the last ice age, the North Sea was a great plain, and anthropological material, as well as the remains of animals such as mammoths, are sometimes recovered by trawlers. Also, because human societies have always made use of water, sometimes the remains of structures that these societies built underwater still exist (such as the foundations of crannogs, [9] bridges and harbors) when traces on dry land have been lost. As a result, underwater archaeological sites cover a vast range including: submerged indigenous sites and places where people once lived or visited that have been subsequently covered by water due to rising sea levels; wells, cenotes, wrecks (shipwrecks; aircraft); the remains of structures created in water (such as crannogs, bridges or harbors); other port-related structures; refuse or debris sites where people disposed of their waste, garbage and other items, such as ships, aircraft, munitions and machinery, by dumping into the water.

Underwater archaeology is often complementary to archaeological research on terrestrial sites because the two are often linked by many and various elements including geographic, social, political, economic and other considerations. As a result, a study of an archaeological landscape can involve a multidisciplinary approach requiring the inclusion of many specialists from a variety of disciplines including prehistory, historical archaeology, maritime archaeology, and anthropology. There are many examples. One is the wreck of the VOC ship Zuytdorp lost in 1711 on the coast of Western Australia, where there remains considerable speculation that some of the crew survived and, after establishing themselves on shore, intermixed with indigenous tribes from the area. [10] The archaeological signature at this site also now extends into the interaction between indigenous people and the European pastoralists who entered the area in the mid-19th century. [11]

Research potential

There are many reasons why underwater archaeology can make a significant contribution to our knowledge of the past. In the shipwreck field alone, individual shipwrecks can be of significant historical importance either because of the magnitude of loss of life (such as the Titanic) or circumstances of loss ( Housatonic was the first vessel in history sunk by an enemy submarine). [12] [13] Shipwrecks such as Mary Rose can also be important for archaeology because they can form a kind of accidental time capsule, preserving an assemblage of human artifacts at the moment in time when the ship was lost. [14] [15]

Sometimes it is not the wrecking of the ship that is important, but the fact that we have access to the remains of it, especially where the vessel was of major importance and significance in the history of science and engineering (or warfare), due to being the first of its type of vessel. The development of submarines, for example, can be traced via underwater archaeological research, via the Hunley , which was the first submarine to sink an enemy ship (Hunley also had unique construction details not found in previous vessels and was one of the few historic warships ever raised intact); [13] the ResurgamII, the first powered submarine; [16] and Holland 5 , which provides insight into the development of submarines in the British Navy. [17]

UNESCO Convention

All traces of human existence underwater which are one hundred years old or more are protected by the UNESCO Convention on the Protection of the Underwater Cultural Heritage. This convention aims at preventing the destruction or loss of historic and cultural information and looting. It helps states parties to protect their underwater cultural heritage with an international legal framework. [18] On the basis of the recommendations defined in the above-mentioned UNESCO Convention various European projects have been funded such as the CoMAS project [19] for in situ conservation planning of underwater archaeological artefacts. [20] [21] [22]

Challenges

Underwater sites are inevitably difficult to access, and more hazardous, compared with working on dry land. In order to access the site directly, diving equipment and diving skills are necessary. The depths that can be accessed by divers, and the length of time available at depths, are limited. For deep sites beyond the reach of divers, submarines or remote sensing equipment are needed.

For a marine site, while some form of working platform (typically a boat or ship) is often needed, shore-based activities are common. Notwithstanding, underwater archaeology is a field plagued by logistics problems. A working platform for underwater archaeology needs to be equipped to provide for the delivery of air for example, recompression and medical facilities, or specialist remote sensing equipment, analysis of archaeological results, support for activities being undertaken in the water, storage of supplies, facilities for conservation for any items recovered from the water, as well as accommodation for workers. Equipment used for archaeological investigation, including water dredge and airlifts create additional hazards and logistics issues. Moreover, marine sites may be subject to strong tidal flows or poor weather which mean that the site is only accessible for a limited amount of time. Some marine creatures also pose a threat to diver safety.

Underwater sites are often dynamic, that is they are subject to movement by currents, surf, storm damage or tidal flows. Structures may be unexpectedly uncovered, or buried beneath sediments. Over time, exposed structures will be eroded, broken up and scattered. The dynamic nature of the environment may make in-situ conservation infeasible, especially as exposed organics, such as the wood of a shipwreck, are likely to be consumed by marine organisms such as piddocks. In addition, underwater sites can be chemically active, with the result that iron can be leached from metal structures to form concretions. The original metal will then be left in a fragile state. Artifacts recovered from underwater sites need special care.

Visibility may be poor, because of sediments or algae in the water and lack of light penetration. [23] This means that survey techniques that work well on land (such as triangulation), generally can not be used effectively under water.

In addition it can be difficult to allow access to the results of the archaeological research as underwater sites do not provide good outreach possibilities or access for the general public. [24] Work has been done to bridge this difficulty through the use of the World Wide Web for webcasting projects, or dedicated virtual reality systems [25] that allow users to perform a virtual diving into an interactive 3D reconstruction of the underwater archaeological site. An example is the excavation of the Queen Anne's Revenge [26] and the QAR DiveLive program, [27] a live interactive virtual field trip to the wrecksite.

Techniques

Although specialized techniques and tools have been developed to address the challenges of working under water, the archaeological goals and process are essentially the same as in any other context. Investigating an underwater site however, is likely to take longer and be more costly than an equivalent terrestrial one. [5]

An important aspect of project design is likely to be managing the logistics of operating from a boat and of managing diving operations. The depth of water over the site, and whether access is constrained by tides, currents and adverse weather conditions will create substantial constraints on the techniques that can feasibly be used and the amount of investigation that can be carried out for a given cost or in a set timescale. Many of the most carefully investigated sites, including the Mary Rose have relied substantially on avocational archaeologists working over a considerable period of time. [15]

As with archaeology on land, some techniques are essentially manual, using simple equipment (generally relying on the efforts of one or more scuba divers), while others use advanced technology and more complex logistics (for example requiring a large support vessel, with equipment handling cranes, underwater communication and computer visualization).

Position fixing

Knowing the location of an archaeological site is fundamental to being able to study it. In the open sea there are no landmarks, so position fixing is generally achieved using GPS. Historically, sites within sight of the shore would have been located using transects. A site may also be located by visually surveying some form of marker (such as a buoy) from two known (mapped) points on land. The depth of water at a site can be determined from charts or by using the depth sounding sonar equipment that is standard equipment on ships. Such sonar can often be used to locate an upstanding structure, such as a shipwreck, once GPS has placed the research vessel in approximately the right location.

Site survey

Side-scan sonar image of shipwreck Aid in Estonia. Laevavrakk "Aid".png
Side-scan sonar image of shipwreck Aid in Estonia.

The type of survey required depends on the information that is needed to resolve archaeological questions, but most sites will need at least some form of topographical survey and a site plan showing the locations of artifacts and other archaeological material, where samples were taken and where different types of archaeological investigation were carried out. Environmental assessment of archaeological sites will also require that environmental conditions (water chemistry, dynamic properties) as well as the natural organisms present on the site are recorded. For shipwrecks, particularly post-industrial age shipwrecks, pollution threats from wreck material may need to be investigated and recorded.

The simplest approach to survey is to carry out three-dimensional surveying by divers using depth gauges and tape measurements. [28] Research shows that such measurements are typically less accurate than similar surveys on land. [29] Where it is not practical or safe for divers to physically visit a site, Remotely Operated Vehicles (ROVs) enable observation and intervention with control by personnel located at the surface. [30] The low technology approach of measuring using tape measures and depth gauges can be replaced with a more accurate and quicker high technology approach using acoustic positioning. [31] ROV technology was used during the Mardi Gras Shipwreck Project. The "Mardi Gras Shipwreck" sank some 200 years ago about 35 miles off the coast of Louisiana in the Gulf of Mexico in 4,000 feet (1,200 meters) of water. [32]

Remote sensing or Marine Geophysics [33] is generally carried out using equipment towed from a vessel on the surface and therefore does not require any one, or any equipment to actually penetrate to the full depth of the site. Sensitive sonar, especially side-scan sonar or multi-beam sonar [34] may be used to image an underwater site. Magnetometry [35] can be used to locate metal remains such as metal shipwrecks, anchors and cannon. Sub-bottom profiling [36] [37] utilizes sonar to detect structures buried beneath sediment.

Recording

LAMP archaeologist recording a scaled drawing of the ship's bell discovered on the late 18th century "Storm Wreck" off St. Augustine, Florida Diver&shipsbell.jpg
LAMP archaeologist recording a scaled drawing of the ship's bell discovered on the late 18th century "Storm Wreck" off St. Augustine, Florida

A variety of techniques are available to divers to record findings underwater. Scale drawing is the basic tool of archaeology and can be undertaken underwater. Pencils will write underwater on permatrace, plastic dive slates, or matt laminated paper.

Photography and videography are the mainstays of recording, which has become much more convenient with the advent of reasonably priced digital still and HD video cameras. Cameras, including video cameras can be provided with special underwater housings that enable them to be used for underwater videography. Low visibility underwater and distortion of image due to refraction mean that perspective photographs can be difficult to obtain. However, it is possible to take a series of photographs at adjacent points and then combined into a single photomontage or photomosaic image of the whole site. 3D photogrammetry has also become a very popular way to image underwater cultural materials and shipwreck sites. [38] [39]

Excavation

Where intrusive underwater excavation is appropriate, silts and sediments can be removed from an area of investigation using a water dredge or airlift. When used correctly, these devices have an additional benefit in tending to improve the visibility in the immediate vicinity of the investigation. For very deep sea excavation manned and unmanned submersibles are sometimes used to view sites. Underwater photography and sonar imaging can also be conducted from these platforms which assists the recording process.

Archaeological science

A variety of archaeological sciences are used in underwater archaeology. Dendrochronology is an important technique especially for dating the timbers of wooden ships. It may also provide additional information, including the area where the timber was harvested (i.e. likely to be where the ship was built) and whether or not there are later repairs or reuse of salvaged materials. Because plant and animal material can be preserved underwater, archaeobotany and archaeozoology have roles in underwater archaeology. For example, for submerged terrestrial sites or inland water, identification of pollen samples from sedimentary or silt layers can provide information on the plants growing on surrounding land and hence on the nature of the landscape. Information about metal artifacts can be obtained through X-ray of concretions. Geology can provide insight into how the site evolved, including changes in sea-level, erosion by rivers and deposition by rivers or in the sea.

Artifact recovery and conservation

Artifacts recovered from underwater sites need stabilization to manage the process of removal of water and conservation. [40] [41] The artifact either needs to be dried carefully, or the water replaced with some inert medium (as in the case of The Mary Rose). Artifacts recovered from salt water, particularly metals and glass need be stabilized following absorption of salt or leaching of metals. In-situ conservation of underwater structures is possible, but consideration needs to be given to the dynamic nature of the site. Changes to the site during intrusive investigation or removal of artifacts may result in scouring which exposes the site to further deterioration.

Interpretation and presentation of underwater archaeology

Diver trails also called wreck trails can be used to allow scuba-divers to visit and understand archaeological sites that are suitable for scuba-diving [42] One excellent example is the Florida Public Archaeology Network's (FPAN) "Florida Panhandle Shipwreck Trail." [43] The Florida Panhandle Shipwreck Trail features 12 shipwrecks including artificial reefs and a variety of sea life for diving, snorkeling and fishing offshore of Pensacola, Destin, Panama City and Port St. Joe, Florida. [44] Otherwise presentation will typically rely on publication (book or journal articles, web-sites and electronic media such as CD-ROM). Television programs, web videos and social media can also bring an understanding of underwater archaeology to a broad audience. The Mardi Gras Shipwreck Project [45] integrated a one-hour HD documentary, [32] short videos for public viewing and video updates during the expedition as part of the educational outreach. Webcasting is also another tool for educational outreach. For one week in 2000 and 2001, live underwater video of the Queen Anne's Revenge Shipwreck Project was webcast to the Internet as a part of the QAR DiveLive [27] educational program that reached thousands of children around the world. [46] Created and co-produced by Nautilus Productions and Marine Grafics, this project enabled students to talk to scientists and learn about methods and technologies utilized by the underwater archaeology team. [47] [48]

Environmental impact

Underwater archeology can have many impacts on the environment such as destroying habitats and disrupting wildlife that may be in the area of the archeological site.

History

Publications

Publication is an essential part of the archaeological process and is particularly crucial for underwater archaeology, where sites are generally not accessible and it is often the case that sites are not preserved in-situ.

The specialist journals on maritime archaeology, which include the long established International Journal of Nautical Archaeology , The Bulletin of the Australasian Institute for Maritime Archaeology (AIMA) and the recently launched Journal of Maritime Archaeology publish articles about maritime archaeological research and underwater archaeology. [49] However, research on underwater sites can also be published in mainstream archaeological journals, or thematic archaeological journals. Some institutions also make their unpublished reports, often called 'Grey Literature', accessible thereby allowing access to far more detail and a wider range of archaeological data than is otherwise the case with books and journals. An example is the works of the Department of Maritime Archaeology at the Western Australian Museum. [50]

The public interest market is covered by a number of diving, shipwreck and underwater archaeology books, beginning with the works of Jacques Cousteau.

The techniques of underwater archaeology are also documented in published works, including a number of handbooks, [51] [52] and Muckelroy's classic work on Maritime Archaeology. [5]

See also

Related Research Articles

<span class="mw-page-title-main">Maritime archaeology</span> Archaeological study of human interaction with the sea

Maritime archaeology is a discipline within archaeology as a whole that specifically studies human interaction with the sea, lakes and rivers through the study of associated physical remains, be they vessels, shore-side facilities, port-related structures, cargoes, human remains and submerged landscapes. A specialty within maritime archaeology is nautical archaeology, which studies ship construction and use.

<span class="mw-page-title-main">Shipwreck</span> Physical remains of a beached or sunk ship

A shipwreck is the wreckage of a ship that is located either beached on land or sunken to the bottom of a body of water. Shipwrecking may be intentional or unintentional. There were approximately three million shipwrecks worldwide as of January 1999, according to Angela Croome, a science writer and author who specialized in the history of underwater archaeology.

<span class="mw-page-title-main">Wreck diving</span> Recreational diving on wrecks

Wreck diving is recreational diving where the wreckage of ships, aircraft and other artificial structures are explored. The term is used mainly by recreational and technical divers. Professional divers, when diving on a shipwreck, generally refer to the specific task, such as salvage work, accident investigation or archaeological survey. Although most wreck dive sites are at shipwrecks, there is an increasing trend to scuttle retired ships to create artificial reef sites. Diving to crashed aircraft can also be considered wreck diving. The recreation of wreck diving makes no distinction as to how the vessel ended up on the bottom.

<span class="mw-page-title-main">Remotely operated underwater vehicle</span> A tethered underwater mobile device operated by a remote crew

A remotely operated underwater vehicle (ROUV) or remotely operated vehicle (ROV) is a free-swimming submersible craft used to perform underwater observation, inspection and physical tasks such as valve operations, hydraulic functions and other general tasks within the subsea oil and gas industry, military, scientific and other applications. ROVs can also carry tooling packages for undertaking specific tasks such as pull-in and connection of flexible flowlines and umbilicals, and component replacement. They are often used to visit wrecks at great depths beyond the capacities of submersibles for research purposes, such as the Titanic, amongst others.

Defenses against swimmer incursions are security methods developed to protect watercraft, ports and installations, and other sensitive resources in or near vulnerable waterways from potential threats or intrusions by swimmers or scuba divers.

<span class="mw-page-title-main">Marine salvage</span> Recovering a ship or cargo after a maritime casualty

Marine salvage is the process of recovering a ship and its cargo after a shipwreck or other maritime casualty. Salvage may encompass towing, lifting a vessel, or effecting repairs to a ship. Salvors are normally paid for their efforts. However, protecting the coastal environment from oil spillages or other contaminants from a modern ship can also be a motivator, as oil, cargo, and other pollutants can easily leak from a wreck and in these instances, governments or authorities may organise the salvage.

<span class="mw-page-title-main">Treasure hunting</span> Physical search for treasure

Treasure hunting is the physical search for treasure. For example, treasure hunters try to find sunken shipwrecks and retrieve artifacts with market value. This industry is generally fueled by the market for antiquities.

<span class="mw-page-title-main">Archaeology of shipwrecks</span> Study of human activity through the analysis of shipwreck artifacts

The archaeology of shipwrecks is the field of archaeology specialized most commonly in the study and exploration of shipwrecks. Its techniques combine those of archaeology with those of diving to become Underwater archaeology. However, shipwrecks are discovered on what have become terrestrial sites.

<span class="mw-page-title-main">Salvage diving</span> Diving work associated with the recovery of vehicles, cargo and structures

Salvage diving is the diving work associated with the recovery of all or part of ships, their cargoes, aircraft, and other vehicles and structures which have sunk or fallen into water. In the case of ships it may also refer to repair work done to make an abandoned or distressed but still floating vessel more suitable for towing or propulsion under its own power. The recreational/technical activity known as wreck diving is generally not considered salvage work, though some recovery of artifacts may be done by recreational divers.

The Center for Maritime Archaeology and Conservation (CMAC) was created in May 2005 by the regents of Texas A&M University.

<span class="mw-page-title-main">Whitefish Point Underwater Preserve</span> Reserve to protect and conserve shipwrecks and historical resources in Lake Superior

The Whitefish Point Underwater Preserve was established in 1987 to protect and conserve shipwrecks and historical resources on 376 square miles (970 km2) of Lake Superior bottomlands in Whitefish Bay and around Whitefish Point, Michigan. The formation of the Michigan Underwater Preserves helped stop controversy over artifact removal from shipwrecks of this area. The preserve is now known for deep, well preserved shipwrecks in clear water accessible to scuba divers with technical skill and experience. The preserve is one of the last places in the Great Lakes to observe shipwrecks without zebra mussel encrustation.

<span class="mw-page-title-main">Florida Public Archaeology Network</span>

The Florida Public Archaeology Network, or FPAN, is a state supported organization of regional centers dedicated to public outreach and assisting Florida municipalities and the Florida Division of Historical Resources "to promote the stewardship and protection of Florida's archaeological resources." FPAN was established in 2004, upon legislation that sought to establish a "Florida network of public archaeology centers to help stem the rapid deterioration of this state's buried past and to expand public interest in archaeology."

Save Ontario Shipwrecks (SOS) is a Provincial Heritage Organization in Ontario, Canada. SOS is a public charitable organization which operates through Local Chapter Committees supported by a Provincial Board of Directors and Provincial Executive.

<span class="mw-page-title-main">Conservation and restoration of shipwreck artifacts</span>

The conservation and restoration of shipwreck artifacts is the process of caring for cultural heritage that has been part of a shipwreck. Oftentimes these cultural artifacts have been underwater for a great length of time. Without conservation, most artifacts would perish and important historical data would be lost. In archaeological terms, it is usually the responsibility of an archaeologist and conservator to ensure that material recovered from a shipwreck is properly cared for. The conservation phase is often time-consuming and expensive, which is one of the most important considerations when planning and implementing any action involving the recovery of artifacts from a shipwreck.

<span class="mw-page-title-main">Nautilus Productions</span> American video production, stock footage, and photography company

Nautilus Productions LLC is an American video production, stock footage, and photography company incorporated in Fayetteville, North Carolina in 1997. The principals are producer/director Rick Allen and photographer Cindy Burnham. Nautilus specializes in documentary production and underwater videography, and produced QAR DiveLive, a live webcast of underwater archaeology filmed at the wreck of the Queen Anne's Revenge in 2000 and 2001.

Valerie Olson van Heest is an American author, explorer, and museum exhibit designer. She is co-founder of the Michigan Shipwreck Research Association.

<span class="mw-page-title-main">Gozo Phoenician shipwreck</span> Phoenician shipwreck near the coast of Malta

The Gozo Phoenician shipwreck is a seventh-century-BC shipwreck of a Phoenician trade ship lying at a depth of 110 meters (360 ft). The wreck was discovered in 2007 during a sonar survey off the coast of Malta's Gozo island. Since 2014 it has been the object of a multidisciplinary project led by University of Malta along with many other national and international entities. The Gozo shipwreck archaeological excavation is the first maritime archaeological survey to explore shipwrecks with divers beyond a depth of 100 meters (330 ft).

<span class="mw-page-title-main">Underwater exploration</span> Investigating or traveling around underwater for the purpose of discovery

Underwater exploration is the exploration of any underwater environment, either by direct observation by the explorer, or by remote observation and measurement under the direction of the investigators. Systematic, targeted exploration is the most effective method to increase understanding of the ocean and other underwater regions, so they can be effectively managed, conserved, regulated, and their resources discovered, accessed, and used. Less than 10% of the ocean has been mapped in any detail, less has been visually observed, and the total diversity of life and distribution of populations is similarly obscure.

Archaeological diving is a type of scientific diving used as a method of survey and excavation in underwater archaeology. The first known use of the method comes from 1446, when Leon Battista Alberti explored and attempted to lift the ships of Emperor Caligula in Lake Nemi, Italy. Just a few decades later, in 1535, the same site saw the first use of a sophisticated breathing apparatus for archaeological purposes, when Guglielmo de Lorena and Frances de Marchi used an early diving bell to explore and retrieve material from the lake, although they decided to keep the blueprint of the exact mechanism secret. The following three centuries saw the gradual extension of diving time through the use of bells and submersing barrels filled with air. In the 19th century, the standard copper helmet diving gear was developed, allowing divers to stay underwater for extended periods through a constant air supply pumped down from the surface through a hose. Nevertheless, the widespread utilisation of diving gear for archaeological purposes had to wait until the 20th century, when archaeologists began to appreciate the wealth of material that could be found under the water. This century also saw further advances in technology, most important being the invention of the aqualung by Émile Gagnan and Jacques-Yves Cousteau, the latter of whom would go on to use the technology for underwater excavation by 1948. Modern archaeologists use two kinds of equipment to provide breathing gas underwater: self-contained underwater breathing apparatus (SCUBA), which allows for greater mobility but limits the time the diver can spend in the water, and Surface-supplied diving equipment, which is safer but more expensive, and can only be used in shallower waters.

References

  1. "Underwater and Maritime Archeology in Latin America and the Caribbean". p. 21. docid 10408690.
  2. Akesson, Per. "A history of underwater archaeology". Nordic Underwater Archaeology. Archived from the original on 2018-12-09. Retrieved 2005-10-01.
  3. Gibbins, David & Adams, Jonathan (2001). "Shipwrecks and maritime archaeology". World Archaeology. 32 (3): 279–291. doi:10.1080/00438240120048635. S2CID   37301382.
  4. "How underwater archaeology reveals hidden wonders". Culture. 2019-08-02. Archived from the original on August 2, 2019. Retrieved 2020-09-16.
  5. 1 2 3 Muckelroy, K. (1978). Maritime archaeology. Cambridge University Press. ISBN   978-0-521-29348-8.
  6. "Broken Wings". Western Australian Museum . Government of Western Australia . Retrieved 5 June 2015.
  7. "Port Royal Project: Home".
  8. University of Southampton. ":: University of Southampton". Archived from the original on 19 August 2007.
  9. "The Scottish Crannog Centre".
  10. "Zuiddorp (Zuytdorp) (1712/06) North of Kalbarri". Shipwreck Databases Western Australian Museum.
  11. "The Zuytdorp Story table of contents". Archived from the original on 3 June 2004. Retrieved 11 November 2010.
  12. "TIP – United States Senate Inquiry". Archived from the original on 2007-12-13. Retrieved 2007-12-18.
  13. 1 2 "Housatonic i". Naval History and Heritage Command. 15 January 2015. Retrieved 5 June 2015.
  14. "BBC World Service – Documentaries – What Lies Beneath".
  15. 1 2 "The Mary Rose".
  16. "Advisory Committee on Historic Wreck Sites Annual Report 2005" (PDF). Department for Digital, Culture, Media and Sport. June 2006. Archived from the original (PDF) on 14 January 2007. Retrieved 5 June 2015.
  17. "Heritage Minister Andrew McIntosh Acts To Protect Wreck Site Of Prototype Submarine". Department for Digital, Culture, Media and Sport. 4 January 2005. Archived from the original on 26 September 2006. Retrieved 5 June 2015.
  18. UNESCO, Convention on the protection of the Underwater Cultural Heritage
  19. "CoMAS project". Archived from the original on 19 September 2016. Retrieved 24 January 2018.
  20. Scalercio, Emiliano; Sangiovanni, Francesco; Gallo, Alessandro; Barbieri, Loris (2021). "Underwater Power Tools for In Situ Preservation, Cleaning and Consolidation of Submerged Archaeological Remains". Journal of Marine Science and Engineering. 9 (6): 676. doi: 10.3390/jmse9060676 .
  21. Electromechanical devices for supporting the restoration of underwater archaeological artefacts. MTS/IEEE OCEANS 2015 - Genova: Discovering Sustainable Ocean Energy for a New World. doi:10.1109/OCEANS-Genova.2015.7271597.
  22. A ROV for supporting the planned maintenance in underwater archaeological sites. MTS/IEEE OCEANS 2015 - Genova: Discovering Sustainable Ocean Energy for a New World. doi:10.1109/OCEANS-Genova.2015.7271602.
  23. Cantelas, FJ; Rodgers, BA (1997). "Tools, Techniques, and Zero Visibility Archaeology". In: EJ Maney, Jr and CH Ellis, Jr (Eds.) Diving for Science...1997. Proceedings of the American Academy of Underwater Sciences (17th Annual Scientific Diving Symposium). Archived from the original on 3 April 2009. Retrieved 20 October 2010.{{cite journal}}: CS1 maint: unfit URL (link)
  24. "Deepwater Archaeology in Oil and Gas – By Kimberly L. Faulk". Museum of Underwater Archaeology. 14 December 2010.
  25. Bruno, F.; Barbieri, L.; Muzzupappa, M.; Tusa, S.; Fresina, A.; Oliveri, F.; Lagudi, A.; Cozza, A.; Peluso, R. (2019). "Enhancing learning and access to Underwater Cultural Heritage through digital technologies: the case study of the "Cala Minnola" shipwreck site". Digital Applications in Archaeology and Cultural Heritage. 13: e00103. doi:10.1016/j.daach.2019.e00103. S2CID   155526789.
  26. Southerly, C; Gillman-Bryan, J (2003). "Diving on the Queen Anne's Revenge". In: SF Norton (Ed). Diving for Science...2003. Proceedings of the American Academy of Underwater Sciences (22nd Annual Scientific Diving Symposium). Archived from the original on 19 February 2009. Retrieved 20 October 2010.{{cite journal}}: CS1 maint: unfit URL (link)
  27. 1 2 "Live from Morehead City, it's Queen Anne's Revenge". ncdcr.gov.
  28. "3D survey resource site from 3H". Archived from the original on 10 February 2006. Retrieved 24 January 2018.
  29. Holt, Peter. "Research on the accuracy of tape survey methods from 3H" (PDF). Archived from the original (PDF) on 1 June 2006. Retrieved 24 January 2018.
  30. ""ROV" stands for remotely operated vehicle". Ocean Explorer. Office of Ocean Exploration . Retrieved 5 June 2015.
  31. "The Acoustic Tracking System".
  32. 1 2 "Mystery Mardi Gras Shipwreck". Nautilus Productions. Archived from the original on 2015-06-13. Retrieved 2015-04-10.
  33. "Geophysical Survey Methodology".
  34. Multibeam sonar evaluated by Wessex Archaeology as part of ALSF funded "Wrecks on the Seabed" project
  35. Magnetometry evaluated by Wessex Archaeology as part of ALSF funded "Wrecks on the Seabed" project
  36. Sub-bottom profiling sonar evaluated by Wessex Archaeology as part of ALSF funded "Wrecks on the Seabed" project
  37. Sub-bottom profile investigation of the Grace Dieu from The University of Southampton
  38. Van Damme, T (2015). "Computer Vision Photogrammetry for Underwater Archaeological Site Recording in a Low-Visibility Environment" (PDF). ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. XL55: 231–238. Bibcode:2015ISPArXL55..231V. doi: 10.5194/isprsarchives-XL-5-W5-231-2015 . Retrieved 24 April 2016.
  39. S.Tusa (2019). "Enhancing learning and access to Underwater Cultural Heritage through digital technologies: the case study of the "Cala Minnola" shipwreck site". Digital Applications in Archaeology and Cultural Heritage. 13: e00103. doi:10.1016/j.daach.2019.e00103. S2CID   155526789.
  40. Hamilton, Donny L. (1997). Basic Methods of Conserving Underwater Archaeological Material Culture. Washington D. C.: Texas A&M University. Archived from the original on 2017-12-02. Retrieved 2017-12-01.
  41. Veilleux, Carol A. "Conservation Methods Of Underwater Artifacts". Oregon State University. Archived from the original on 2 May 2004. Retrieved 5 June 2015.
  42. e.g. Souter, C., 2006 Cultural Tourism and Diver Education. In Maritime Archaeology: Australian Approaches. The Springer Series in Underwater Archaeology. Staniforth, M. & Nash, M. (eds) Springer, New York.
  43. "Florida Panhandle Shipwreck Trail". Florida Panhandle Dive Trail.
  44. Blair, Kimberly. "Florida Panhandle Shipwreck Trail beckons divers". usatoday.com. Retrieved 17 August 2015.
  45. "Mardi Gras Shipwreck". uwf.edu. Archived from the original on 16 May 2015.
  46. C Southerly and J Gillman-Bryan. (2003). "Diving on the Queen Anne's Revenge". In: SF Norton (Ed). Diving for Science...2003. Proceedings of the American Academy of Underwater Sciences (22nd Annual Scientific Diving Symposium). Archived from the original on 19 February 2009. Retrieved 3 July 2008.{{cite journal}}: CS1 maint: unfit URL (link)
  47. "Apple, QuickTime help with underwater diving trip". Macworld.
  48. "Blackbeard's Glowing Shipwreck". P3 Update. Archived from the original on 2015-04-02. Retrieved 2015-05-13.
  49. "Journal of Maritime Archaeology". springer.com.
  50. "Research Areas". Western Australian Museum. Retrieved 20 October 2010.
  51. Ruppé, Carol V; Barstad, Janet F, eds. (2002). International Handbook of Underwater Archaeology. The Springer Series in Underwater Archaeology. Springer. doi:10.1007/978-1-4615-0535-8. ISBN   9780306463457.
  52. Archaeology Underwater, The NAS Guide to Principles and Practice; eds Martin dean, Ben Ferrari, Ian Oxley, Mark Redknap and Kit Watson. Published by Nautical Archaeology Society, Archetype Press, 1992 ISBN   1-873132-25-5