Fact-checked by Grok 2 weeks ago

Mid-Atlantic Ridge

The Mid-Atlantic Ridge () is a massive underwater and divergent tectonic plate boundary that bisects the Atlantic Ocean, extending approximately 16,000 kilometers (10,000 miles) from the near southward to the near . It forms part of the global system, the longest mountain chain on at nearly 65,000 kilometers (40,000 miles), where new is continuously created as the North American and South American plates (to the west) and the Eurasian and plates (to the east) slowly diverge. This process drives at an average rate of 2.5 centimeters per year, though rates vary between 2 and 5 centimeters annually along different segments. Geologically, the MAR is characterized by a central , often comparable in depth and width to the Grand Canyon, flanked by rugged abyssal hills and volcanic features rising several hundred meters above the surrounding seafloor. The ridge's crest typically lies at depths of about 2,500 meters below , gradually deepening to around 4,000 meters as the crust ages and cools away from the axis. rises from through fissures in the rift, erupting as basaltic lava that solidifies to form new crust, while frequent small earthquakes and occasional volcanic cones mark the dynamic spreading process. The ridge is segmented by transform faults and non-transform offsets, creating discrete spreading centers tens to hundreds of kilometers long, which contribute to its uneven topography. Beyond its role in , the Mid-Atlantic Ridge is a for hydrothermal vent systems, where superheated, mineral-rich fluids support unique chemosynthetic ecosystems independent of sunlight. These features, including "black smoker" chimneys, not only drive but also provide insights into Earth's geochemical cycles and potential analogs for . Ongoing exploration, such as NOAA expeditions, continues to reveal the ridge's volcanic processes and structural complexities, underscoring its importance in understanding global geodynamics.

Geographical Overview

Location and Extent

The Mid-Atlantic Ridge traces a sinuous path through the Atlantic Ocean basin, beginning at its northern terminus where it connects with the Gakkel Ridge in the near the northeastern coast of , and extending southward approximately 16,000 km (10,000 miles) to the Bouvet Triple Junction in the South Atlantic near the island of Bouvetøya. This extensive feature runs roughly parallel to the North and South American continents on the west and the African and Eurasian continents on the east, forming a central divide within the ocean basin. The ridge is commonly divided into northern, central, and southern segments based on tectonic and morphological transitions, with the northern segment extending from the Arctic connection southward to about 50°N, the central segment spanning the equatorial region, and the southern segment continuing to the around 55°S. Major fracture zones offset the ridge axis, notably the Charlie-Gibbs Fracture Zone at approximately 52°N, which offsets the Reykjanes Ridge (the northern segment) by about 350 km to the west from the more southerly segments of the ridge, and the Romanche Fracture Zone near the equator at around 0° to 4°S, which creates a significant lateral offset in the central segment. These offsets contribute to the ridge's segmented character and influence ocean circulation patterns across . Positioned centrally in the Atlantic, the ridge lies roughly 1,500 to 3,000 km from the eastern seaboard of the and the western coasts of and , depending on latitude, with closer approaches to in the north where it emerges as a feature. The Mid-Atlantic Ridge serves as a separating the North American and Eurasian plates from the South American and plates. rates along the ridge vary from about 2 cm/year in the northern segment to around 3.5 cm/year in the southern segment near the Bouvet , with intermediate rates of approximately 2.5-3 cm/year in the central equatorial region.

Physical Dimensions and Morphology

The Mid-Atlantic Ridge forms a prominent that rises 2–3 km above the surrounding abyssal plains, with a broad base spanning 1,000–1,500 km in width. Its axial zone typically reaches depths of 2,500–3,000 m below , creating a topographic high relative to the deeper floor at around 4,000–5,000 m. This elevation profile results from material at the , though detailed formation processes are addressed elsewhere. Along its crest, the ridge features a central that extends for much of its length, measuring 20–40 km in width and reaching depths up to 2 km relative to the adjacent ridge flanks. The valley is flanked by rugged, faulted terrain with steep scarps and irregular , transitioning outward to smoother abyssal plains. As a slow-spreading ridge with rates of about 2–4 cm per year, its morphology is characterized by pronounced tectonic extension and deep valleys, contrasting with the smoother, more volcanically dominated profiles of faster-spreading ridges. The ridge is segmented by transform faults, which offset the axis into discrete sections typically 30–100 km long, interspersed with non-magmatic gaps up to 30 km wide. Recent high-resolution bathymetric surveys conducted between 2023 and 2025 have refined these measurements, highlighting variations in segment relief and fault patterns along the northern and equatorial portions. These offsets contribute to the overall linear yet discontinuous structure of the ridge across the Atlantic basin.

Historical Discovery and Exploration

Early Hypotheses and Observations

During the mid-19th century, efforts to lay telegraph cables led to the first systematic soundings of the Atlantic Ocean floor, revealing unexpectedly shallow regions in the central basin. In 1853, U.S. Navy Lieutenant Otway Berryman, aboard the USS Dolphin, recorded depths as shallow as 1,720 fathoms (approximately 3,140 meters) north of the , indicating a mid-ocean shoal that facilitated cable laying and was termed the "Telegraphic Plateau." These findings suggested a broad elevation rather than a uniform deep basin, though the full extent remained unclear due to limited data points. The HMS Challenger expedition (1872–1876) provided more comprehensive evidence through 492 deep-sea soundings across global oceans, including multiple traverses of . Crew members, including naturalist John Murray, detected consistent shallow areas averaging 1,500–2,000 fathoms (2,750–3,650 meters) along the mid-Atlantic, contrasting with deeper abyssal plains on either side. Initially interpreted as a vast "submarine plateau" or elevated ridge, these observations were compiled into early bathymetric charts, highlighting a linear feature bisecting the ocean but lacking detail on its rugged morphology. In 1912, incorporated these mid-ocean shallows into his hypothesis, proposing that the shallow Atlantic ridge marked an active rift where continents had separated, with material filling the gap. Although Wegener lacked direct knowledge of the ridge's full structure, he cited the soundings and earlier surveys as supporting evidence for ongoing separation, estimating a drift rate of about 250 cm per year based on geological fits. His theory, published in Die Entstehung der Kontinente und Ozeane, faced skepticism but drew on the ridge's central position as a conceptual link between continental margins. Early 20th-century advancements in cable laying and dedicated oceanographic voyages further delineated the feature. Surveys during transatlantic cable installations in the 1900s and 1910s, combined with ship soundings from expeditions like the 1910 Michael Sars cruise, confirmed the continuity of mid-Atlantic shoals from Iceland southward. Oceanographer John Murray synthesized these data into influential maps, such as his 1899 Bathymetrical Chart of the Oceans and 1912 Atlantic chart, portraying a prominent submarine ridge rising 2,000–3,000 meters above surrounding seafloors, though still depicted as a smooth plateau rather than a fractured chain. These early hypotheses and observations were constrained by methodological limitations, relying on wire-line soundings spaced kilometers apart, which captured only isolated depth points without lateral profiles or seismic data. Comprehensive cross-sections of the ridge's valley and peaks awaited acoustic technologies like in the mid-20th century, leaving pre-1920s interpretations tentative and focused on broad elevations rather than dynamic .

20th-Century Mapping and Expeditions

The advancements in sonar technology developed during significantly enhanced the capability for detailed bathymetric surveys of the ocean floor, enabling the collection of dense echo-sounding data that revealed previously undetected submarine features like the Mid-Atlantic Ridge. In 1947–1948, oceanographer Maurice Ewing led expeditions aboard the research vessel to investigate the Mid-Atlantic Ridge, collecting echo-sounding profiles and rock samples that contributed to early understandings of its . Building on this foundation, in the early 1950s, geologist Bruce Heezen and cartographer at University's Lamont-Doherty Geological Observatory compiled extensive echo-sounding records from naval and vessels to create the first comprehensive bathymetric map of the North Atlantic seafloor. Tharp's analysis in 1952 first revealed the deep along the ridge's axis. Their work, which meticulously plotted thousands of depth profiles, unveiled the Mid-Atlantic Ridge as a continuous global feature extending over 40,000 kilometers and highlighted the pervasive running along its crest. This landmark map was published in 1957, fundamentally reshaping understandings of oceanic and providing visual evidence for the ridge's symmetrical structure. The 1953 expedition of the , part of preparatory efforts for the (IGY, 1957–1958), employed closely spaced echo sounders to traverse the Mid-Atlantic Ridge, producing the first detailed profiles that confirmed the rift valley's extent across a broad section of the Atlantic and linked it to the global mid-ocean ridge system. Subsequent IGY voyages, including those by U.S. vessels like the and international collaborators, expanded coverage through coordinated seismic and bathymetric surveys, verifying the ridge's continuity from the to the South Atlantic. By the 1960s, integrated profiles from these efforts, combined with additional cruises, yielded full cross-sectional views of the , demonstrating depths up to 2,000 meters below the surrounding seafloor and widths of 20–40 kilometers in key segments. Recent retrospectives from (IODP) expeditions, such as those in reviewing core samples from the ridge axis, have reaffirmed the accuracy of these mid-20th-century mappings by correlating historical with modern seismic data and drill cores.

Geological Formation

Seafloor Spreading Mechanism

The Mid-Atlantic Ridge functions as a divergent plate boundary, where upwelling of hot material from Earth's interior drives the creation of new , gradually pushing the adjacent tectonic plates apart. This process, known as , occurs as convection currents in the cause the to rise beneath the ridge axis, reducing pressure and initiating of rock at depths typically ranging from 50 to 100 km. The resulting basaltic magma, less dense than the surrounding solid , ascends buoyantly through fractures toward the surface, where it erupts or intrudes to form the ridge's crustal layer primarily composed of mid-ocean ridge basalt (MORB). The ascent of culminates at the axis, where it solidifies into new seafloor, with the plates diverging at a relatively slow rate of 2 to 5 cm per year along the Mid-Atlantic . This spreading rate varies slightly along different segments but averages about 2.5 cm per year, leading to symmetric progression of crustal age away from the , as older is continuously displaced outward. for this symmetry is preserved in the pattern of magnetic stripes on the seafloor, formed when iron-rich minerals in the cooling align with Earth's geomagnetic field, recording periodic reversals in . These stripes exhibit mirrored normal and reversed anomalies on either side of the , confirming the ongoing creation and outward migration of crust. A key piece of supporting evidence for at the Mid-Atlantic Ridge comes from the Vine-Matthews-Morley hypothesis, proposed in 1963, which interpreted these linear magnetic anomalies as imprints of geomagnetic reversals frozen into the newly formed . According to this model, the symmetric distribution of reversed stripes about the ridge axis directly results from continuous extrusion and subsequent plate separation. The half-spreading rate, representing the velocity of one plate away from the axis, can be calculated using the formula: \text{Half-spreading rate} = \frac{\text{distance from ridge [axis](/page/Axis)}}{\text{[age of](/page/Age_Of) crust at that distance}} For example, applying this to the Mid-Atlantic Ridge yields an average half-spreading rate of approximately 2.5 cm per year, consistent with observed crustal ages increasing progressively from zero at the to tens of millions of years farther away.

Tectonic Interactions and Plate Boundaries

The Mid-Atlantic Ridge (MAR) serves as a divergent plate boundary, separating the from the in the northern and the from the (specifically the Nubian subplate) in the southern . This configuration facilitates the ongoing creation of new as the plates diverge, with full spreading rates varying along the ridge from approximately 2 cm/year in slower segments to up to 4 cm/year in faster northern sections near . These interactions exemplify the ridge's role in the global plate mosaic, where lateral plate motions drive continuous seafloor expansion and contribute to the widening of the Atlantic basin. The MAR is segmented and offset by numerous transform faults, which accommodate the differential motion between adjacent spreading segments and result in oblique spreading patterns. These faults typically offset the ridge axis by 10 to 300 km, with prominent examples including the Charlie-Gibbs Fracture Zone, which displaces the ridge by over 300 km at around 52°N and generates significant strike-slip earthquakes due to its right-lateral motion. Such offsets not only segment the ridge into discrete volcanic and tectonic provinces but also concentrate seismic activity along the fault planes, where frictional sliding between plates releases accumulated . At its northern and southern termini, the MAR participates in triple junctions where three plates converge. The , located near 38°N, marks the intersection of the North American, Eurasian, and African (Nubian) plates, influencing regional volcanism and deformation across the archipelago. Similarly, the Bouvet Triple Junction in the South Atlantic, near 54°S, connects the MAR with the South American-Antarctic Ridge, involving the South American, African (Nubian), and Antarctic plates, and features complex ridge-ridge-transform geometry that has evolved through oblique rifting over millions of years. Recent geophysical studies from 2023 to 2025 have revealed rift-to-ridge inheritance effects, where structural discontinuities from the initial rifting during of Pangea approximately 200 million years ago continue to imprint the segmentation of the modern . Seismic imaging of the eastern North American margin demonstrates that magmatic segmentation during rifting persisted, aligning with present-day locations and influencing ridge morphology without requiring ongoing plume activity. This inheritance underscores how ancient tectonic fabrics from dispersal shape contemporary oceanic spreading dynamics.

Key Features

Rift Valleys and Fracture Zones

The central of the Mid-Atlantic Ridge () is a prominent axial depression formed primarily through normal faulting associated with tectonic extension during . This valley typically measures 1–2 km in relief relative to the surrounding ridge flanks, with widths ranging from 16 to 62 km, averaging around 30–40 km across various segments. The fault-bounded structure results from the brittle failure of the cooling as new is generated at rates of approximately 2–5 cm per year, leading to pronounced graben-like morphology. In slow-spreading environments like the , the is notably deeper and more rugged compared to fast-spreading mid-ocean ridges, where axial highs often replace valleys due to sustained magmatic support and thinner . This distinction arises from the limited melt supply at slow rates, promoting greater tectonic extension and deeper fault scarps before magmatic replenishment occurs. Fracture zones along the represent inactive extensions of transform faults beyond the ridge axis, manifesting as linear bathymetric scars that offset the ridge and accumulate sediments in their lows. These zones, such as the Romanche Fracture Zone near the , can reach depths of up to 7.8 km in features like the Vema Deep, serving as sediment-filled troughs that disrupt the otherwise continuous ridge trend. The Romanche Trench, for instance, offsets the ridge by over 900 km and acts as a conduit for deep-water circulation while preserving a record of past tectonic offsets. The MAR is segmented into discrete ridge sections, typically 50–100 km long, separated by transform faults or non-transform offsets that accommodate changes in spreading direction. These segments influence crustal architecture, with thinner —often 3–5 km thick—developing near segment ends and overlaps due to reduced and increased tectonic strain, compared to thicker crust (up to 8–9 km) at segment centers. Recent geomagnetic data from International Ocean Discovery Program (IODP) Site U1555, located on the eastern flank of the MAR, provide insights into rift evolution spanning approximately 2.7 million years, revealing patterns of magnetic reversals and excursions that trace variations in spreading rates and axial processes over geological time.

Hydrothermal Vents and Volcanic Activity

Hydrothermal vents along the Mid-Atlantic Ridge (MAR) are primarily manifested as black smokers, which are chimneys that emit superheated, mineral-rich fluids at depths typically ranging from 2,000 to 4,000 meters. These vents discharge fluids reaching temperatures of up to 350°C, laden with dissolved metals such as iron, copper, zinc, and sulfides, which precipitate upon mixing with cold seawater to form dark plumes and chimney structures. The first black smoker vents on the MAR were discovered in 1985 at the Trans-Atlantic Geotraverse (TAG) hydrothermal field, located at approximately 26°N in the rift valley, where active venting occurs at about 3,650 meters depth and supports massive sulfide deposits up to 50 meters tall. Volcanic activity on the MAR is characterized by episodic eruptions that produce pillow lavas and sheet flows along the ridge axis, reflecting the slow-spreading nature of the system. Pillow lavas, formed by the of molten into rounded lobes, dominate in rugged terrains, while smoother sheet flows occur in axial volcanic ridges where lava spreads more rapidly before cooling. Recent expeditions have revealed ongoing magmatic expressions, including the discovery of three new high-temperature black smoker vent fields in along a 700-kilometer stretch from the to the Charlie-Gibbs Fracture Zone at around 52°N, highlighting dynamic hydrothermal systems tied to recent . Seismicity associated with these vents and volcanic processes includes frequent shallow earthquakes, generally with magnitudes less than 6, resulting from normal faulting in the brittle upper crust along the ridge axis. In addition, 2025 observations have documented deeper earthquakes at 10-20 km depth beneath the , attributed to CO₂ degassing from ascending melts that induces brittle failure in the otherwise ductile . These seismic events underscore the role of volatiles in facilitating and migration. The venting and volcanic processes contribute to the formation of polymetallic deposits, rich in , , lead, , and silver, which accumulate as massive sulfides around active and extinct vents. These deposits, exemplified by the field, represent significant potential resources for deep-sea mining, though extraction poses environmental challenges. Hydrothermal activity at these sites also sustains unique chemosynthetic ecosystems, as explored in broader studies.

Associated Landforms

Oceanic Islands and Hotspots

The archipelago consists of nine volcanic islands situated at the where the Mid-Atlantic Ridge intersects the North American, Eurasian, and Nubian plates. These islands result from the interaction between the spreading ridge and a , with geochemical evidence from plume-derived basalts along the ridge indicating an upper-mantle thermal anomaly that has influenced regional volcanism. The plume's northward drift at 1–2 cm/year over the past 85 million years has shaped the track, though the primary formation of the occurred through enhanced melt production near the ridge between 10 and 4 million years ago. Ongoing volcanic activity persists, as demonstrated by the seismo-volcanic crisis beginning in June 2022 on , involving thousands of earthquakes and heightened monitoring for potential eruptions, which continues as of November 2025 with elevated seismic activity and periodic alert level increases. Further south along the Mid-Atlantic Ridge, the island group represents a remote manifestation of in the South Atlantic, located approximately 400 km east of the ridge axis. This cluster of islands, including proper, Nightingale, Inaccessible, and Gough, formed over a unrelated to the adjacent ridge spreading but influenced by it through channeled mantle flow. The 1961 eruption of the main island's produced a new and lava flows, prompting temporary evacuation of the inhabitants and highlighting the site's eruptive hazards. The island chain traces the underlying plume track, extending westward via the Walvis Ridge to the African and eastward across the ridge, with age-progressive seamounts documenting over 130 million years of plume activity. Recent ⁴⁰Ar/³⁹Ar dating of basalts from the conjugate Rio Grande Rise confirms more than 30 million years of sustained plume-ridge interaction in this system, driving episodic excess magmatism and crustal thickening. Additional hotspot-related features along the Mid-Atlantic Ridge include seamounts and oceanic core complexes that expose deeper mantle materials. The Atlantis Massif, at 30°N on the ridge, is a prominent corrugated dome representing an ultramafic core complex uplifted through long-lived detachment faulting, revealing serpentinized peridotites from the mantle. This structure, formed near a transform fault-ridge intersection, provides direct evidence of mantle exhumation without significant magmatic input, contrasting with plume-driven features. Ascension Island, located about 80 km west of the ridge at 7°S, exemplifies another isolated hotspot with basaltic volcanism influenced by proximity to the spreading axis and the Ascension Fracture Zone. Isotopic studies of its rocks show enriched signatures consistent with plume-derived melts interacting with ridge processes. These dispersed islands and seamounts illustrate how mantle plumes intermittently intersect the ridge, generating localized volcanic chains distinct from continuous subaerial exposures elsewhere.

Iceland as a Subaerial Segment

Iceland straddles the northern portion of the , where the divergent plate boundary emerges above , making it the only segment of the global ridge system. Upon reaching land, the spreading center bifurcates into three principal neovolcanic zones: the Western Volcanic Zone, the Eastern Volcanic Zone, and the North Volcanic Zone, each characterized by active rifting and that directly expose the mechanics of on land. The Eastern Volcanic Zone, in particular, serves as a key site for observing crustal extension, with fissure swarms and central volcanoes illustrating the ongoing separation of the North American and Eurasian plates. The formation of Iceland results from prolonged interaction between the underlying hotspot and the Mid-Atlantic Ridge, initiating around 16 million years ago when the oldest exposed basaltic rocks began accumulating. This hotspot-ridge interaction has produced a thickened crust measuring 30–40 km, compared to the typical 6–7 km elsewhere along the ridge, through enhanced melting and repeated volcanic additions. A notable manifestation of this activity was the 2010 eruption of , a in the Eastern Volcanic Zone, which ejected ash plumes reaching up to 10 km altitude and caused widespread aviation disruptions across the North Atlantic. Iceland's landforms vividly reflect the subaerial expression of processes, with the central highlands dominated by broad plateaus, elongated swarms, and subglacial eruption products that parallel the axial valleys and volcanic ridges seen in settings. On the Peninsula, which represents the onshore continuation of the Reykjanes Ridge segment, extensive geothermal fields—such as those at Krýsuvík and Hengill—exhibit intense hydrothermal venting, fault scarps, and lava flows that mimic the black smokers and basaltic constructs of underwater rifts. Ongoing monitoring via global positioning system (GPS) networks across Iceland reveals plate divergence at a rate of approximately 1.9–2 cm per year, with measurable widening of rift zones and associated deformation in real time. This active spreading is underscored by recurrent eruptions, including the 2023 eruption at Fagradalsfjall, which produced approximately 0.016 km³ of lava, and subsequent eruptions in the Reykjanes Fires series at nearby sites such as Sundhnúkur through 2025, with cumulative lava volumes exceeding 1 km³ since 2021, demonstrating the persistent magmatic replenishment driving subaerial rifting.

Scientific and Environmental Significance

Contributions to Plate Tectonics Theory

In the 1960s, detailed bathymetric mapping of the (MAR) provided critical evidence that revolutionized geological thought, directly informing Harry Hess's seminal 1962 hypothesis of . Hess proposed that molten magma rises along the ridge crest, solidifies to form new , and spreads symmetrically outward, pushing continents apart and explaining the young age of ocean floor rocks compared to continental ones. This mechanism, rooted in observations of the MAR's central position in the Atlantic basin, challenged the prevailing view of a static and laid the groundwork for integrating seafloor dynamics with Alfred Wegener's earlier ideas. Key milestones in this included the discovery of symmetric magnetic stripes flanking the MAR, which confirmed the spreading process. In 1963, Frederick Vine and Drummond Matthews analyzed marine magnetic data from the ridge near 27°N, revealing alternating bands of normal and reversed polarity in the basaltic crust, symmetric about the ridge axis and correlating with known geomagnetic reversals. These patterns indicated continuous crust formation at the ridge followed by lateral migration, providing quantitative support for Hess's model at rates of about 1-2 cm per year. Concurrently, and Bruce Heezen's pioneering maps, compiled from profiles in the and published prominently in and 1968, visually depicted the continuous MAR as a global rift system, shattering the notion of a featureless ocean floor and prompting widespread recognition of active crustal dynamics. By the early , these lines of evidence—combined with earthquake distributions and observations—led to the broad acceptance of as the unifying theory of Earth's geodynamics. The serves as the archetypal example of a divergent plate boundary, where the North American and Eurasian (or ) plates separate, exemplifying how such ridges drive global plate motions. This configuration influenced foundational models of zones, where older, denser oceanic sinks back into , balancing crustal creation at ridges like the . Furthermore, the ridge's role in the Atlantic's opening informs the , a model of assembly and breakup over hundreds of millions of years; the represents the phase of this cycle, linking divergent spreading to eventual and continental elsewhere. Recent geophysical studies continue to validate these concepts by connecting the MAR to ancient tectonic events. A 2023 analysis of seismic data along the Eastern North American Margin revealed discontinuous igneous additions beneath the East Coast Magnetic Anomaly, aligning with fracture zones that trace back to the MAR's early segmentation during the Pangea breakup approximately 200 million years ago. This work underscores how initial rifting at what became the MAR initiated the Atlantic's formation, with magmatic pulses shaping the passive margin's structure.

Biodiversity and Ecosystem Studies

The Mid-Atlantic Ridge hosts unique chemosynthetic ecosystems centered around hydrothermal vents, where life depends on chemical energy from sulfide-rich fluids rather than sunlight. Microbes oxidize to produce energy, forming the base of food webs that support dense communities of specialized organisms, including giant tubeworms (Riftia pachyptila) and clams (Calyptogena magnifica) that harbor . These ecosystems were first documented in 1977, and since then, over 590 new animal species have been identified at global vent sites, with many analogous communities thriving along the Mid-Atlantic Ridge, such as at the and fields. The Mid-Atlantic Ridge Ecosystem Project (MAR-ECO), initiated in the 2000s as part of the Census of Marine Life and continuing through international collaborations, has provided comprehensive insights into the ridge's pelagic and benthic . This multidisciplinary effort employed advanced sampling techniques, including remotely operated vehicles and trawls, to map distributions and interactions across depths from 100 to 4,500 meters along the northern ridge between and the . Key findings reveal that the ridge acts as a biological corridor, concentrating deep-pelagic fishes like and through enhanced migration patterns that facilitate reproduction and foraging, while benthic communities exhibit high influenced by topographic features. These fragile ecosystems face significant environmental threats, particularly from prospective deep-sea targeting polymetallic sulfides near vents, which could disrupt fluid flows and chemical gradients essential for chemosynthetic . Mining operations may release sediments and toxins, smothering benthic habitats and altering microbial communities over kilometers, with potential irreversible losses given the slow recovery rates of deep-sea species. Additionally, is weakening the Atlantic Meridional Overturning Circulation (AMOC), which interacts with ridge , potentially reducing nutrient and oxygen levels that sustain pelagic migrations and overall along the ridge. Expeditions from 2023 to 2025 have uncovered new fields and species in previously unexplored ridge segments, highlighting ongoing discoveries amid these pressures as of November 2025. For example, a 2023 international expedition discovered three new fields along the southern MAR, expanding known habitats for chemosynthetic life. Furthermore, studies indicate that CO2 degassing from ridge volcanism contributes to localized , lowering pH levels near vents and stressing calcifying organisms like mussels and , exacerbating global effects.