Integrated Ocean Drilling Program

(IODP may also refer to the International Ocean Discovery Program)
Integrated Ocean Drilling Program
Established 2003 (2003)
Field of research
Geology
Website www.iodp.org

The Integrated Ocean Drilling Program (IODP) was an international marine research program. The program used heavy drilling equipment mounted aboard ships to monitor and sample sub-seafloor environments. With this research, the IODP documented environmental change, Earth processes and effects, the biosphere, solid earth cycles, and geodynamics.[1]

The program began a new 10-year phase with the International Ocean Discovery Program, from the end of 2013.

Scope

The Integrated Ocean Drilling Program (IODP) brought together scientists from different countries and scientific disciplines to conduct investigations of the Earth deep below the sea-floor. IODP gave scientists the opportunity to:

  1. recover geological records and rock samples
  2. investigate and document ocean- and climate-change through time
  3. explore the presence of primitive life below the seafloor
  4. verify remote, near-seafloor observatories
  5. gain understanding of how tectonic plates move and recycle themselves into the deep mantle

Focus on Earth

IODP was conceived in 2003 as a 10-year Earth science and research program. IODP scientists were drawn from universities and institutes located all across its member countries. Two previous scientific ocean drilling programs, Deep Sea Drilling Project and Ocean Drilling Program, generated abundant information about Earth’s dynamic nature including tectonic processes, ocean circulation, climate change, continental rifting, and ocean basin formation. With IODP, scientific ocean drilling continued to provide scientists with in-situ studies of critical processes related to Earth’s short-term change and long-term variability. IODP provided diverse drilling resources to meet specific requirements of each planned drilling project.

IODP focused on ocean basins to study the interdependent processes with particular emphases on factors controlling climate change, the vast circulation of fluids within Earth’s crust, the nature of life on and within Earth, and the dynamics of tropospheric formation and recycling.

Scientific ocean drilling represented the longest running and most successful international collaboration among the Earth sciences. Scientific ocean drilling began in 1961 with the first sample of oceanic crust recovered aboard the CUSS 1, a modified U.S. Navy barge. American author John Steinbeck, also an amateur oceanographer, documented Project Mohole for LIFE Magazine.

Legacy programs

The Deep Sea Drilling Project (DSDP), established in June 1966, operated the Glomar Challenger in drilling and coring operations in the Atlantic, Pacific, and Indian Oceans, as well as in the Mediterranean and Red Seas. The Challenger’s coring operations enabled DSDP to provide the next intellectual step in verifying the hypothesis of plate tectonics associated with seafloor spreading, by dating basal sediments on transects away from the Mid-Atlantic Ridge.

Deep Ocean Explorer: Glomar Challenger
Total distance penetrated below sea floor 325,548 m
Total interval cored 170,043 m
Total core recovered and stored 97,056 m
Overall core recovery 57%
Number of core samples recovered 19,119
Number of sites investigated 624
Deepest penetration into basaltic ocean crust 1,714 m
Maximum penetration into basaltic ocean crust 1,350 m
Deepest water (Leg 60, Site 461A) 7,044 m
Total distance traveled (nautical miles) 375,632

In June 1970, the Challenger's DSDP engineers devised a way to replace worn drill bits and then re-enter boreholes for deeper drilling while in the Atlantic Ocean off the coast of New York, in 10,000 feet (3,048 meters) of water. This required the use of sonar scanning equipment and a large-scale re-entry cone.

Process-oriented Earth studies continued from 1985 until 2003 aboard the JOIDES Resolution, which replaced the Glomar Challenger in January 1985 as DSDP morphed into the Ocean Drilling Program (ODP). The JOIDES Resolution is named for the 200-year-old HMS Resolution which explored the Pacific Ocean and Antarctica under the command of Captain James Cook.

The Ocean Drilling Program contributed significantly to increased scientific understanding of Earth history, climate change, plate tectonics, natural resources, and geohazards. ODP discoveries included validation of:

  1. fluids circulating through the ocean floor;
  2. the formation of gigantic volcanic plateaus at phenomenal rates unknown today;
  3. natural methane frozen deep within marine sediments as gas hydrate;
  4. a microbial community living deep within oceanic crust;
  5. climate change cycles

IODP funding agencies

National consortia and government funding agencies supported IODP science and drilling platform operations. Participation in IODP was proportional to investment in the program.

Lead agencies

Two lead agencies formally established IODP. In April 2003, officials from Japan’s Ministry of Education, Culture, Sports, Science and Technology (MEXT) and the U.S. National Science Foundation (NSF) signed a memorandum of understanding (MOU) in which they agreed to form and jointly operate the Integrated Ocean Drilling Program. Japan’s interest in the post-ODP era was signified when “Ocean Drilling in the 21st Century” (OD21) was established in 1994. OD21 included plans for construction of a state-of-the-art, riser-equipped scientific drilling vessel capable of reaching Earth’s mantle. A series of international meetings explored how this goal could be integrated with other scientific objectives expressed by scientific communities in the United States, Europe, and the People’s Republic of China. An IODP office at NSF was responsible for administering commingled funds from NSF, MEXT, and other IODP members to support IODP science-operating costs.

Contributing member

The European Consortium for Ocean Research Drilling (ECORD) was established in December 2003 with 13 European countries to represent the European contribution in IODP. The consortium grew into a collaborative group of 17 European nations (Austria, Belgium, Denmark, Finland, France, Germany, Iceland, Ireland, Italy, The Netherlands, Norway, Poland, Portugal, Spain, Sweden, Switzerland and The United Kingdom) and Canada that together comprise an IODP-funding agency. Working alongside Japan and the United States, ECORD provided the IODP scientific community with access to mission-specific platforms, which chosen to fulfill specific scientific objectives. These platforms have limited space on board for labs and scientists, and require an onshore science meeting to describe, process, and analyze the sediment samples collected immediately following a drilling expedition.

Associate members

In April 2004, the People’s Republic of China joined IODP as an Associate Member through sponsorship of China’s Ministry of Science and Technology (MOST). China’s participation in IODP has given the Chinese marine science community a new impetus and increased their opportunity for deep-sea research. Chinese scientists participated in research expeditions and represent China’s interests in the IODP Science Advisory Structure.

The Republic of Korea joined IODP as an Associate Member in June 2006 through the sponsorship of the Korea Institute of Geoscience and Mineral Resources (KIGAM). South Korea’s memorandum of understanding with the lead agencies created the Interim Asian Consortium.

Ministry of Earth Sciences (MoES), Government of India joined the IODP in 2008 as an Associate member. Since then, the National Centre for Antarctic and Ocean Research (NCAOR), Goa has been designated by India to look after all IODP related activities in India (IODP-India). In this direction, an international workshop on IODP drilling in Indian Ocean was organized in Goa during October 17–18, 2011. The workshop was co-hosted by IODP Management International and ANZIC.

Hundreds of international Earth and ocean scientists participated in IODP on a voluntary basis. Participation took many forms: submission of a drilling proposal; sailing on an expedition; participation in an advisory capacity; attendance at a planning workshop or topical symposium. The program’s central management office, IODP Management International, coordinated an integrated work plan between and among all IODP organizational partners. An annual program plan was written each fiscal year and included objectives and tasks necessary for drilling vessel operation, from science coordination to publications, data management, and outreach.

Uniquely IODP

IODP distinguishes itself from its legacy programs by employing multiple drilling technologies/platforms and science/drilling operators to acquire sediment and rock samples and to install monitoring instrumentation beneath the seafloor. Samples and data collected during IODP drilling expeditions are available to scientists and teachers on an open-access basis, once members of the expedition parties have completed their initial studies.

Planning IODP drilling: science advisory structure

Drilling proposal process

Drilling proposals originated with science proponents, often researchers in geology, geophysics, microbiology, paleontology, or seismology. Once submitted to IODP, the proposal was carefully evaluated by the Science Advisory Structure (SAS), a group of technical review panels. Only those proposals judged as the greatest value based on scientific and technical merit were scheduled for implementation.

SAS panels provided advice on drilling proposals to both proponents and IODP management. Drilling proposals were accepted twice a year, in April and October, and could be submitted to IODP electronically via their website.

The science plan

A ten-year program plan called the Initial Science Plan (ISP) guided IODP investigation. Specific scientific themes were emphasized in the ISP:

  1. investigation into the deep biosphere and subseafloor life;
  2. climate change;
  3. solid Earth cycles; and
  4. geodynamics

As described in the ISP, IODP sought to develop better understandings of:

Tools critical to these goals included a riser-equipped drilling vessel, a riserless vessel, additional platforms suited to mission specific expeditions, enhanced downhole measurement devices, and long-term monitoring instrumentation.

Engineering proposals

An engineering proposal submission process, initiated in April 2007, facilitated the acquisition of existing or latent technology to be used in IODP operations.

Science and drilling operators

Drilling operations were conducted and managed by three IODP implementing organizations:

Each drilling expedition was led by a pair of co-chief scientists, with a team of scientists supported by a staff scientist. Each implementing organization provided a combination of services: technical, operational, and financial management; logging; laboratory; core repository; data management; and publication. Although each implementing organization was responsible for its own platform operations and performance, its science operations was funded by the lead agencies.

The operators conducted the following expeditions during the IODP:[2]

Expedition Title
310 Juan de Fuca Hydrogeology
302 Arctic Coring Expedition
303 North Atlantic Climate 1
304 Oceanic Core Complex Formation, Atlantis Massif 1
305 Oceanic Core Complex Formation, Atlantis Massif 2
306 North Atlantic Climate 2
307 Porcupine Basin Carbonate Mounds
308 Gulf of Mexico Hydrogeology
309 Superfast Spreading Rate Crust 2
310 Tahiti Sea Level
311 Cascadia Margin Gas Hydrates
312 Superfast Spreading Rate Crust 3
313 New Jersey Shallow Shelf
314 NanTroSEIZE Stage 1: LWD Transect
315 NanTroSEIZE Stage 1: Megasplay Riser Pilot
316 NanTroSEIZE Stage 1: Shallow Megasplay and Frontal Thrusts
317 Canterbury Basin Sea Level
318 Wilkes Land Glacial History
319 NanTroSEIZE Stage 2: Riser/Riserless Observa
320 Pacific Equatorial Age Transect I
321 Pacific Equatorial Age Transect II / Juan de Fuca
322 NanTroSEIZE Stage 2: Subduction Input
323 Bering Sea Paleoceanography
324 Shatsky Rise Formation
325 Great Barrier Reef Environmental Changes
326 NanTroSEIZE Stage 3: Plate Boundary Deep Riser 1
327 Juan de Fuca Hydrogeology
328 Cascadia ACORK Observatory
329 South Pacific Gyre Subseafloor Life
330 Louisville Seamount Trail
331 Deep Hot Biosphere
332 NanTroSEIZE Stage 2: Riserless Observatory
333 NanTroSEIZE Stage 2: Subduction Inputs 2 and Heat Flow
334 Costa Rica Seismogenesis Project (CRISP)
335 Superfast Spreading Rate Crust 4
336 Mid-Atlantic Ridge Microbiology
337 Deep Coalbed Biosphere off Shimokita
338 NanTroSEIZE Stage 3: Plate Boundary Deep Riser 2
339 Mediterranean Outflow
340 Lesser Antilles Volcanism and Landslides
340T Atlantis Massif Oceanic Core Complex
341 Southern Alaska Margin Tectonics, Climate & Sedimentation
341S SCIMPI
342 Paleogene Newfoundland Sediment Drifts
343 Japan Trench Fast Drilling Project
343T Japan Trench Fast Drilling Project II
344 Costa Rica Seismogenesis Project A Stage 2
345 Hess Deep Plutonic Crust
346 Asian Monsoon
347 Baltic Sea Paleoenvironment
348 Nankai Trough Seismogenic Zone Experiment Stage 3, Plate Boundary Deep Riser

Drilling vessels and platforms

IODP employed two dedicated drilling vessels, each sponsored by a lead agency and managed by their respective implementing organization:

JOIDES Resolution – riserless

Main article: JOIDES Resolution

The U.S.-sponsored drilling vessel was operated throughout the Ocean Drilling Program and the first phase of IODP. The vessel then underwent a rebuild, allowing for increased laboratory space; improved drilling, coring, and sampling capacity; and enhanced health, safety, and environmental protection systems on board.[3]

Chikyu – riser-equipped

Main article: Chikyu Hakken
Chikyu

Japan began building a state-of-the-art scientific drilling vessel for research in 2001 with the intent of reaching Earth’s mantle and drilling into an active seismogenic zone. The resulting drilling vessel, Chikyu (Japanese for "Planet Earth") features a riser drilling system, a dynamic positioning system, and a high-density mud circulation system to prevent borehole collapse during drilling, among other assets. Chikyu can berth 150 people, cruise at 12 knots, and drill more than 7,000 meters below the seafloor in water depths exceeding 2,000 meters. Chikyu was damaged during the tsunami of March 11, 2011, and was out-of-service for several months.[4] Chikyu returned to ocean drilling in April 2012.

Mission-specific platforms

ECORD commissioned ships on an expedition-by-expedition basis, depending on specific scientific requirements and environment. ECORD contracted the use of three icebreakers for the Arctic Coring Expedition (2004), drilling vessels diving for use in shallow Tahitian (2005) and Australian waters (2010), where scientists sampled fossil coral reefs to investigate the rise in global sea levels since the last ice age, and a liftboat for sampling the New Jersey Shallow Shelf (2009). Mission-specific expeditions required substantial flexibility.

Extending IODP to the science community

Publications, data management, online tools, and databases are in development to support information- and resource-sharing, so as to expand the ranks of scientists who engage in ocean drilling investigations.

Publication and data management

IODP publications are freely available online and a data management system integrates core and laboratory data collected by all three implementing organizations and the two IODP legacy programs. A web-based search system will eventually aggregate post-expedition data and related publications. Requests for data and samples can be made online.

Site Survey Data Bank (SSDB)

A web-based Site Survey Data Bank enabled proponents to access and deposit the large amounts of data required to document potential drill sites for evaluation. This data was reviewed to assure IODP expeditions could meet their objectives and comply with safety and environmental requirements.

Core repositories

Three IODP core repositories located in Bremen, Germany (IODP Bremen Core Repository), College Station, Texas (IODP Gulf Coast Repository), and Kochi, Japan, archive cores based on geographical origin. Scientists may visit any one of the facilities for onsite research or request a loan for analysis or for teaching purposes. Archived cores include not only IODP samples, but also those retrieved in the two IODP legacy programs (DSDP and ODP).

References

  1. IODP mission page
  2. Sweeney, Aaron. "Completed Integrated Ocean Drilling Program Expeditions – IODP". www.iodp.org. Retrieved 2016-02-29.
  3. Riserless drilling vessel JOIDES Resolution : http://www.iodp-usio.org/Publications/IODPbro2.pdf
  4. Japanese Research Ship Damaged by Tsunami
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