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Integrated Ocean Drilling Program

The Integrated Ocean Drilling Program (IODP) was an international scientific collaboration dedicated to advancing understanding of Earth's history, , and subsurface processes through targeted drilling expeditions from 2003 to 2013. Launched on October 1, 2003, as the successor to the Ocean Drilling Program (ODP), it was established via a signed in April 2003 between Japan's Ministry of Education, Culture, Sports, Science and Technology (MEXT) and the U.S. (NSF). Financed by 26 member countries and managed by IODP-Management International (IODP-MI), the program emphasized multidisciplinary research guided by its Initial Science Plan, focusing on key themes such as the , , and cycles and . To achieve its objectives, IODP employed a flexible fleet of drilling platforms, including the riserless U.S.-flagged vessel for routine coring, Japan's riser-capable Chikyu for deep and high-pressure drilling, and mission-specific platforms for specialized operations in challenging environments. Over its decade-long run, the program conducted 52 expeditions across global ocean basins, recovering core samples from sediments, rocks, fluids, and microorganisms to depths exceeding previous efforts, with notable achievements including the first successful riserless drilling into an in 2006 and evidence of a tropically warm during the Eocene in 2004. These efforts involved scientists from over 40 countries, with data and samples archived in three international repositories to support ongoing research. IODP's organizational structure included implementing organizations like the U.S. Implementing Organization (USIO), Japan's Center for Deep Earth Exploration (CDEX), and Europe's Consortium for Ocean Research with Development (ECORD), alongside a science advisory structure to evaluate proposals and plan expeditions. Building on the legacies of the (DSDP, 1968–1983) and ODP (1983–2003), it expanded international partnerships and technological capabilities, paving the way for its successor, the (IODP), which began in 2013 and continued until 2024, transitioning to the International Ocean Drilling Programme (IODP³) starting in 2025.

Overview and Objectives

Program Goals and Scope

The Integrated Ocean Drilling Program (IODP), launched in 2003, aimed to advance the understanding of Earth's history, structure, and dynamic processes through systematic subseafloor exploration via drilling. Its core mission focused on recovering and cores from the to investigate key scientific challenges, including the and subseafloor microbial life, past environmental and changes, and cycles such as tectonic and geodynamic processes. Building on the successes of predecessor programs like the Ocean Drilling Program (ODP), IODP emphasized international collaboration to address these objectives through targeted drilling expeditions. The program's primary objectives centered on obtaining high-quality core samples to study paleoclimate variations, tectonic evolution, subseafloor ecosystems, and records of geohazards such as earthquakes and tsunamis. Specific targets included drilling into seismogenic zones to examine fault mechanics, exploring gas hydrate reservoirs for their role in and systems, recovering continuous stratigraphic records of climate events, and penetrating to understand continental breakup and mantle processes. These efforts sought to provide empirical data for modeling Earth's environmental responses across timescales from orbital cycles to millions of years. IODP's scope encompassed global coverage of all major ocean basins, including challenging regions like the and deep-water sites up to 7,000 meters, integrating results with onshore and geophysical surveys for comprehensive . The program promoted interdisciplinary , uniting geologists, biologists, paleoceanographers, geochemists, and scientists to interpret in the context of broader . A distinctive feature was its pioneering use of multiple vessel types—riserless drillships for standard operations, riser-equipped vessels for deeper and more stable , and mission-specific platforms for specialized environments—enabling penetration up to 7 kilometers below the seafloor. Over its initial 10-year phase (2003–2013), IODP planned for approximately 200 sites and ultimately visited 250 sites, recovering more than 66 kilometers of core material, averaging over 6 kilometers annually across its platforms.

Timeline and Key Milestones

The Integrated Ocean Drilling Program (IODP) was officially established on October 1, 2003, as the successor to the , with initial funding commitments and planning efforts beginning in 2001 through international agreements and the approval of its Initial Science Plan. The program operated in two main phases: Phase 1 from 2003 to 2008, which primarily utilized the riserless drilling vessel to continue core sampling in deep ocean environments, and Phase 2 from 2008 to 2013, which expanded operations to include the riser-capable Japanese vessel Chikyu and mission-specific platforms for more complex drilling targets. Key milestones included the launch of the first expedition, Expedition 301 (Juan de Fuca Hydrogeology), from June 28 to August 21, 2004, which targeted hydrogeological processes at the off the coast of , . In 2005, planning advanced for the NanTroSEIZE project, a multiyear initiative to drill into the subduction zone to study seismogenesis, with initial operations commencing in September 2007 using the Chikyu. By the program's end, IODP had completed 54 expeditions, recovering approximately 66 kilometers of core samples that advanced understanding of subseafloor microbial ecosystems and geological processes. In 2009, amid the , IODP underwent a restructuring to address reduced funding availability, including reviews of operational entities and interactions to ensure program sustainability. The program concluded in September 2013 after a decade of operations, transitioning seamlessly to the (2013–2024), which built on IODP's framework with renewed funding and expanded scientific priorities.

Historical Context

Predecessor Programs

The (DSDP), a U.S.-led initiative funded primarily by the , operated from 1968 to 1983 and marked the inception of systematic scientific ocean drilling. Using the specialized Glomar Challenger, the program conducted 96 expeditions across major ocean basins, including , Pacific, Indian, Mediterranean, and Red Seas, investigating 624 sites and recovering approximately 97 kilometers of core samples. These efforts yielded the first direct cores from the , penetrating up to 1,080 meters into basaltic layers and providing critical evidence for and , such as symmetric magnetic anomalies and sediment age patterns observed during Leg 3. Building on DSDP's foundations, the Ocean Drilling Program (ODP) represented an international expansion from 1985 to 2003, involving 23 partner nations and shifting to hypothesis-driven research aboard the drillship. The program completed 111 expeditions, drilling around 2,000 holes at over 600 sites worldwide and recovering more than 222 kilometers of , which enabled detailed paleoceanographic reconstructions. Key discoveries included high-resolution records of Earth's cycles, such as Milankovitch orbital forcings influencing ice ages, and insights into systems through targeted near mid-ocean ridges. Technological advancements progressed significantly from DSDP to ODP, evolving from basic rotary and piston coring methods on the Glomar Challenger—which achieved about 57% core recovery but often disturbed soft sediments—to more sophisticated systems in ODP. The hydraulic piston corer, introduced late in DSDP in 1979, was refined into the Advanced Piston Corer for ODP, allowing nearly undisturbed sampling of unconsolidated sediments with recovery rates exceeding 90% in suitable formations. Additionally, ODP incorporated wireline tools for downhole measurements of physical , enhancing data on formation and during drilling. These innovations, coupled with ODP's emphasis on international collaboration, laid the groundwork for subsequent programs' deeper penetrations and multi-platform operations.

Transition from ODP to IODP

The planning phase for the Integrated Ocean Drilling Program (IODP) spanned from 1999 to 2003, building on the successes of the Ocean Drilling Program (ODP) through initiatives like the NSF's MARGINS program and a series of international workshops that shaped the new framework. These efforts emphasized expanding drilling capabilities, particularly through the introduction of riser drilling technology to enable deeper subseafloor penetration beyond the limitations of ODP's non-riser operations. The MARGINS initiative focused on processes, integrating geophysical, geochemical, and biological research to inform IODP's science priorities, while workshops convened scientists from multiple nations to refine the program's structure and address gaps in ocean drilling science. Key innovations in the transition included a shift from ODP's reliance on a single drilling vessel, the , to a multi-platform fleet comprising the refurbished for riserless drilling, Japan's Chikyu for advanced riserless and riser-capable operations, and mission-specific platforms for challenging environments like polar or shallow waters. Funding dynamics also evolved significantly, with major contributions from the U.S. (NSF, reduced relative to ODP), Japan's Ministry of Education, Culture, Sports, Science and Technology (MEXT), the European Consortium for Ocean Research Drilling (ECORD), and other international partners. This redistribution aimed to broaden international commitment and sustainability, while maintaining continuity in core recovery targets informed by ODP's achievements, such as recovering over 200 km of sediment cores. Negotiating the new consortium agreements presented substantial challenges, including reconciling differing national priorities among NSF, MEXT, ECORD, and emerging groups like the Australia-New Zealand International Consortium (ANZIC), amid ODP's impending shortfalls that threatened the continuity of global ocean drilling. Discussions focused on equitable cost-sharing, platform responsibilities, and to ensure broad participation without overburdening any single partner, ultimately requiring multiple rounds of diplomatic and scientific consultations to forge a cohesive international model. These hurdles were compounded by the need to transition ODP's operational infrastructure and scientific advisory bodies into IODP without disrupting ongoing momentum. A pivotal milestone occurred in April 2003 when a was signed between the U.S. (NSF) and Japan's Ministry of Education, Culture, Sports, Science and Technology (MEXT), with the European Consortium for Ocean Research Drilling (ECORD) as a key initial partner, formalizing the program's launch on that year. The initial IODP drilling proposals prioritized high-impact sites, many of which built upon ODP's unscheduled or deferred locations to maximize scientific return and address unresolved questions in Earth's history. This agreement not only secured the program's operational viability but also set the stage for 52 expeditions over the next decade, enhancing global collaboration in marine geosciences.

Organizational Framework

Funding and Membership Structure

The Integrated Ocean Drilling Program (IODP) was primarily funded through an international consortium where the U.S. National Science Foundation (NSF), Japan's Ministry of Education, Culture, Sports, Science and Technology (MEXT), and the European Consortium for Ocean Research Drilling (ECORD) each contributed approximately one-third of the program's operating costs. This tripartite funding model supported the program's substantial operating costs, enabling coordinated scientific ocean drilling expeditions from 2003 to 2013. Membership in IODP was structured into tiers to accommodate varying levels of national commitment and resources. Contributing members, such as the , , the , and , held full voting rights and provided substantial financial support, granting them priority access to expedition participation and decision-making processes. In contrast, associate members like and (prior to 2013) had limited access to program benefits, including samples and , without the obligation of full contributions. This tiered system allowed emerging nations to engage in IODP activities and build capacity while fostering broader international collaboration, ultimately expanding membership to 26 countries by 2013. Contributions to IODP combined cash payments from major agencies with in-kind support essential for operational flexibility. The NSF and MEXT provided direct monetary funding for core activities, while ECORD delivered in-kind resources such as mission-specific platforms for shallow-water and polar drilling, and Japan supplied the for deep-water riser operations. These diverse inputs ensured the program's technological and logistical across global expeditions.

Science Advisory and Governance Bodies

The governance of the Integrated Ocean Drilling Program (IODP) was facilitated by a centralized administrative body and a multifaceted science advisory structure, ensuring coordinated international oversight of scientific priorities and program implementation. IODP Management International (IMI), established as the program's central management office, handled administrative coordination, developed implementation plans, and negotiated operations among implementing organizations while maintaining impartiality across member nations. The (SAS), comprising international committees and panels of scientists, engineers, and technologists nominated by member offices, provided expert guidance on long-range planning, proposal evaluation, and technological development. Within the SAS, the Science Planning Committee (SPC) played a pivotal role in operationalizing scientific objectives by reviewing and ranking drilling proposals, prioritizing expeditions aligned with the program's Initial Science Plan, and advising on scheduling through annual meetings. Complementing this, the Science Advisory Structure Executive Committee (SASEC) served as the highest-level body in the SAS, conducting program evaluations, formulating policy recommendations for the IODP , and ensuring alignment with broader scientific goals across member countries. Governance processes emphasized collaborative decision-making, including annual meetings of the Board of Governors—comprising representatives from funding agencies such as the U.S. (NSF), Japan's Ministry of Education, Culture, Sports, Science and Technology (MEXT), and the European Consortium for Ocean Research Drilling (ECORD)—to approve budgets and strategic directions. Proposals underwent rigorous international by SAS panels, incorporating assessments of engineering feasibility to balance scientific ambition with operational constraints. A distinctive aspect of IODP's advisory framework was its reliance on multi-national panels, drawing diverse expertise from global scientific communities to foster inclusive and innovative program direction. Hundreds of scientists contributed to these panels over the program's decade, shaping the selection and execution of 54 expeditions that advanced understanding of Earth's subsurface history.

Planning and Proposal Process

Development of Science Plans

The development of science plans for the Integrated Ocean Drilling Program (IODP) was initiated in the late 1990s to establish a strategic framework for international drilling research following the Ocean Drilling Program (ODP). The initial science plan, released in 2001 and titled Earth, , and : Scientific Investigations of the Earth System Using Multiple Drilling Platforms and New Technologies, outlined three overarching themes: the and subseafloor , , processes and effects, and cycles and . These themes focused on understanding microbial in extreme subsurface conditions, reconstructing past climate variations and their drivers, and probing tectonic processes like rifting and . The plan was crafted through a collaborative process involving international workshops and conferences between 1998 and 2001, such as the workshop in in 1999, which gathered scientists from multiple nations to integrate insights from prior ODP efforts and identify priorities for advanced drilling technologies. A key aspect of the 2001 plan was the prioritization of drilling transects across critical geological features, such as plate boundaries and margins, to collect continuous records of 's history. It also stressed the integration of core samples with geophysical datasets, including seismic profiles and satellite observations, to model dynamic Earth processes more comprehensively. This approach aimed to address fundamental questions, like the role of subseafloor fluids in and the triggers of rapid environmental shifts. The Science Planning Committee (), an advisory body, played a role in refining these elements through community consultations. These science plans provided the thematic backbone for IODP expeditions, guiding approximately 80% of drilling operations toward high-impact objectives. A prominent example is the Nankai Trough Seismogenic Zone Experiment (NanTroSEIZE), a multi-expedition initiative launched in 2005 and continued through 2013, which served as a flagship for studies by penetrating the seismogenic zone to investigate fault and rupture .

Drilling Proposal Evaluation

The drilling proposal evaluation process in the Integrated Ocean Drilling Program (IODP) was a structured, multi-tiered designed to select expeditions that advanced high-impact scientific objectives while ensuring operational feasibility and safety. Proposals were submitted biannually in and through the program's Support Office, starting with pre-proposals—abbreviated letters of intent—assessed by the Science Planning Committee (SPC) for conceptual strength and potential alignment with the Initial Science Plan, "Earth, Oceans and Life." These pre-proposals underwent initial screening to gauge readiness for full development, with one revision opportunity allowed before advancing; only those demonstrating compelling hypotheses and broad scientific interest proceeded to full proposals, which required detailed integration of site survey data from the Site Survey Data Bank, including geophysical profiles and maps via Form 6 summaries. Full proposals were rigorously evaluated by the Proposal Evaluation Panel (PEP), an international body of experts organized into thematic sub-chairs covering areas like and Change History, Frontiers and Systems, and Earth's Interior Processes. The PEP conducted reviews in plenary sessions and thematic breakouts, assigning "watchdogs" to each proposal for in-depth analysis of strengths and weaknesses; promising submissions were then forwarded for external international to solicit broader input. Engineering feasibility was incorporated through consultation with the Operational (OTF), which provided input on suitability (e.g., riserless versus riser on vessels like the or Chikyū). Proposals received ratings of Excellent (top 10-20%), Good (40-60%), or Fair (20-30%), with dispositions including forwarding to facility boards for scheduling, revision, deactivation, or placement in a "holding bin" pending additional site characterization. High-priority proposals were ranked for scheduled expeditions, while others served as unscheduled contingencies. Evaluation criteria emphasized scientific novelty, interdisciplinary , and transformative potential to address IODP's core themes, such as fundamental processes or dynamics, while requiring clear advancement of program goals through innovative experimental designs that integrated coring, logging, and sampling. Feasibility assessments prioritized adequate site surveys to mitigate risks, to broaden participation (e.g., involving early-career or underrepresented regions), and protocols, including environmental considerations. The process yielded an acceptance rate of approximately 20%, with over the program's 10-year span, submissions leading to 51 expeditions that collectively visited sites and recovered more than 9,400 cores. A notable example is the proposal for Expedition 311 (2005), targeting the Cascadia Margin off the coast to study gas distribution in a zone accretionary prism. Selected for its novelty in linking stability to seismic hazards and paleoclimate records, the expedition drilled five sites (U1325–U1329), recovering pressure cores that provided direct evidence of hydrate-bearing sediments and advanced models of earthquake-prone margins. This project exemplified the criteria by combining geophysical site surveys with interdisciplinary goals in the "Earth in Motion" theme, demonstrating feasibility on the despite challenging seafloor conditions.

Engineering and Operational Planning

Following the approval of drilling proposals, engineering reviews commence to assess the technical feasibility of proposed sites and operations within the (IODP). These reviews, overseen by the , evaluate the need for new technologies or modifications to existing systems, ensuring alignment with the program's scientific objectives. Site surveys play a critical role, providing essential data on seabed conditions, water depths, and geological hazards such as gas hydrates, which could destabilize boreholes or pose safety risks. The maintains a Site Survey Data Bank (SSDB) to compile and verify this data, including seismic profiles and geotechnical investigations, prior to finalizing drill sites. Platform selection is determined based on water depth and operational requirements, with riserless drilling employed for sites in water depths less than approximately 2.5 km using the , while riser drilling is reserved for deeper or more challenging environments on the Chikyū to maintain borehole pressure balance and enable deeper penetration. The Operations Proposal Review Panel (OPRP) and OPCOM recommend the optimal platform, factoring in scientific needs and logistical constraints. then advances through structured phases, including risk assessments conducted by the and Safety Panel (EPSP) using a three-tier framework (low, moderate, high risk) to identify and mitigate potential issues like overpressured formations. Permit acquisitions are coordinated by the Implementing Organizations, often requiring 18 months of lead time, alongside crew training for drilling and scientific personnel to ensure compliance with safety protocols. Integration of logging-while-drilling (LWD) tools, approved by the Scientific Technology Panel (STP), allows real-time downhole measurements to guide coring and enhance data quality. Key challenges in operational planning include weather-related delays, which the Operations Task Force (OTF) accounts for in scheduling, and borehole instability, addressed through advanced coring techniques such as the extended core barrel (XCB) for improved recovery in indurated sediments. For high-risk riser sites, planning extends over about four years, incorporating 3D seismic surveys and multi-step reviews. The IODP achieved core recovery rates often exceeding 90% across expeditions, reflecting high operational effectiveness in meeting drilling targets. A notable adaptation occurred in 2009 during Expedition 319 on the Chikyū, marking the first use of riser drilling in IODP with hybrid systems to handle deep subduction zone environments, enabling observatory installations and deeper sampling while managing fluid circulation and pressure.

Operational Infrastructure

Science Operators and Support

The science operators and support structure of the Integrated Ocean Drilling Program (IODP) were essential for executing expeditions, providing logistical, technical, and scientific coordination across international partners. The U.S. Implementing Organization (USIO), a consortium including , the Consortium for Ocean Leadership, and Lamont-Doherty Earth Observatory of , was responsible for managing non-riser drilling operations, including scheduling for the , maintaining onboard laboratory facilities for core analysis, and handling initial post-cruise to ensure timely scientific outputs. specifically oversaw the operational aspects of the , such as crew and logistics, calibration, and real-time transmission from the vessel to shore-based teams for collaborative monitoring. The European Consortium for Ocean Research Drilling (ECORD) served as the primary operator for mission-specific platforms, enabling specialized drilling in challenging environments like shallow waters or ice-covered regions that were beyond the capabilities of standard vessels. ECORD also coordinated European laboratory support, facilitated international participation by managing nominations and , and provided onshore parties for select expeditions to extend analysis capabilities immediately after coring. This included logistical services such as platform chartering and integration of multidisciplinary teams to address expedition-specific objectives. Japan's contribution was led by the Japan Agency for Marine-Earth Science and Technology (JAMSTEC), which operated the deep-sea drilling vessel , specializing in riser drilling techniques for deeper and more stable boreholes in high-pressure environments. JAMSTEC's role encompassed full expedition management for Chikyū-based operations, including advanced engineering support for riser systems, onboard scientific laboratories equipped for high-temperature drilling, and coordination with global science parties to integrate Japanese expertise in seismogenic zone studies. Across all operators, support for expeditions typically involved approximately 50 scientists and technical staff per voyage, drawn from international pools to ensure diverse expertise in , , and . This included real-time data transmission via for remote and onboard curation of cores to preserve sample integrity during initial descriptions and . These elements collectively enabled the seamless execution of 52 IODP expeditions from 2003 to 2013, fostering high-impact discoveries in Earth's subsurface history.

Drilling Vessels and Platforms

The primary riserless drilling vessel in the Integrated Ocean Drilling Program (IODP) was the , a dynamically positioned capable of operating in water depths up to 8,230 meters while penetrating up to 2,500 meters into underlying sediments. With a of 10,282, the vessel underwent a major upgrade in 2009 at Jurong Shipyard in , which improved its thruster system and overall stability for enhanced deep-water operations. This refurbishment allowed the to serve as the workhorse for the majority of IODP expeditions, recovering samples from diverse environments to study Earth's . Complementing the JOIDES Resolution was the D/V Chikyu, Japan's riser-equipped drilling vessel designed specifically for ambitious deep-drilling targets in tectonically active regions like subduction zones. Boasting a of 56,752, the Chikyu could up to 7,000 meters below the seafloor in water depths of up to 2,500 meters using its advanced riser system, which maintained pressure control during operations. The vessel's first riser drilling operations occurred in , enabling high-recovery coring in challenging conditions that riserless ships could not access. For expeditions requiring specialized access, such as shallow-water sites or ice-covered regions, IODP employed mission-specific platforms (MSPs) in approximately 10% of its operations, providing flexible, tailored solutions beyond the capabilities of the main vessels. These platforms included options like barges for nearshore drilling and ice-class ships for polar environments; a notable example was the 2004 Coring Expedition, which used the Swedish icebreaker Oden and Norwegian supply vessel Vidar Viking to penetrate over 400 meters below the seafloor in water depths of 1,100–1,300 meters amid permanent . Overall, the IODP fleet's enhanced capabilities focused on deeper individual penetrations in key sites, achieving a total core recovery of approximately 97,000 meters across all platforms.

Scientific Outputs and Community Integration

Data Management and Publications

The Integrated Ocean Drilling Program (IODP) employed the JanUS database system to manage real-time expedition data collected during drilling operations on the JOIDES Resolution, facilitating onboard data entry, quality control, and preliminary analysis for parameters such as core logs, physical properties, and initial geochemical measurements. Post-cruise, this data was integrated into a comprehensive relational database containing over 450 tables of marine geoscience information, including detailed core descriptions, digital images, downhole measurements, and geochemical assays, ensuring structured archiving for long-term accessibility. The system supported interoperability through adherence to metadata standards like ISO 19115, allowing integration with global databases such as PANGAEA for broader scientific use. Data management was primarily curated by the U.S. Implementing Organization (USIO), now the JOIDES Resolution Science Operator (JRSO) at , in collaboration with the Consortium for Ocean Research Drilling (ECORD) and other implementing organizations. A one-year moratorium on public data release followed each expedition's completion, protecting the science party's priority access while enabling proprietary analysis before open dissemination. The Science Operator Data and Information System (SEDIS) portal served as a central hub for harvesting and search, linking expedition datasets to physical core repositories for coordinated digital-physical access. IODP's publication policy emphasized rapid and open dissemination of results, with Preliminary Reports issued within two months post-expedition summarizing operations, methods, and initial findings, followed by full Proceedings volumes within 12 months detailing site chapters, , and . The Proceedings of the Integrated Ocean Drilling Program, published by IODP-Management International, transitioned to fully in 2009, making expedition reports freely available online without subscription barriers. Synthesis papers derived from IODP often appeared in high-impact journals such as and , highlighting key discoveries like paleoclimate records or tectonic processes. By 2013, IODP had inspired over 5,000 related peer-reviewed publications, underscoring its substantial scientific output during the program's initial decade.

Core Repositories and Sample Access

The primary core repositories for the Integrated Ocean Drilling Program (IODP) are the Gulf Coast Repository (GCR) at in , USA; the Bremen Core Repository (BCR) at the MARUM Center for Marine Environmental Sciences, , in , ; and the Kochi Core Center (KCC) at Kochi University/JAMSTEC in Kochi, Japan. These facilities collectively hold all IODP cores, including legacy materials from the (DSDP) and Ocean Drilling Program (ODP), stored in climate-controlled, refrigerated conditions to prevent degradation and maintain sample integrity. The GCR focuses on cores from the (eastern regions), , , and , while the BCR manages those from the Atlantic Ocean, , , , and , and the KCC handles cores from the western , (north of 60ºS), , and . Core preservation involves splitting recovered sections into working and archive halves during shipboard processing, with both halves archived indefinitely to support repeated non-destructive examinations. Advanced imaging technologies, such as computed tomography (), enable detailed three-dimensional visualization of internal structures without physical disturbance, facilitating the creation of digital twins for remote virtual access and preliminary analysis. By 2013, these repositories stored approximately 97,000 meters of IODP core material, representing a substantial archive built over the program's first decade. Access to physical samples is available to qualified researchers worldwide through an open proposal system managed via the IODP Sample and Data Requests (SaDR) database, where requests are evaluated by the for scientific merit and adherence to guidelines. Destructive sampling requires justification to limit material loss, with policies ensuring equitable distribution and data-sharing obligations upon receipt. Annually, around 10,000 samples are distributed across the repositories, supporting diverse studies in , , and , though individual facilities report higher volumes such as 50,000 at BCR and over 15,000 at GCR in recent years. Sample requests integrate briefly with IODP systems to align physical materials with associated digital datasets.

Broader Impacts and Legacy

The Integrated Ocean Drilling Program (IODP) significantly advanced scientific understanding of Earth's history, including the dynamics of ice ages and the global . Drilling expeditions provided key evidence for the 100,000-year glacial-interglacial cycles, revealing how orbital variations, atmospheric CO2 levels, and circulation influenced past shifts. Similarly, IODP illuminated long-term processes over 55 million years, linking sediment burial in basins to atmospheric CO2 fluctuations and paleoclimate events like the Paleocene-Eocene Thermal Maximum. In the realm of geohazards, IODP drilling yielded direct evidence for mega-earthquakes along zones, such as episodic seafloor brecciation and deposits recording ancient ruptures, enhancing models of seismic risk. A landmark discovery was the vast extent of the , estimated at 2.9 × 10^{29} microbial cells with 4 Gt of carbon, fundamentally reshaping views of subsurface life and its role in biogeochemical cycles. IODP's educational outreach trained over 2,000 early-career scientists through expedition participation, summer schools, and workshops, fostering a diverse in geosciences. Public engagement efforts included expedition blogs documenting real-time discoveries, video conferences with schools, and collaborations with museums like the to exhibit core samples and promote . These initiatives not only democratized access to ocean drilling but also inspired broader interest in Earth processes among students and the public. Core and data access further amplified these impacts by enabling follow-on studies that integrated IODP findings into interdisciplinary research. The legacy of IODP endures through its influence on successor programs, notably paving the way for the (2013–2023) with expanded scientific themes on , dynamics, and processes. IODP contributions informed climate assessments, such as IPCC reports on and changes, by providing paleoclimate records essential for modeling future scenarios. Economic spin-offs included advancements in drilling technologies, like systems, that enhanced commercial deepwater operations and reduced costs in the energy sector. IODP expeditions linked to high-impact discoveries in .

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