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Alvarez hypothesis

The Alvarez hypothesis, also known as the impact hypothesis, proposes that the mass at the (K–Pg) boundary approximately 66 million years ago, which eliminated about 75% of Earth's species including non-avian dinosaurs, was triggered by the collision of a large with the . This theory was first articulated in by physicist W. Alvarez, his geologist son , nuclear chemist Frank Asaro, and chemist Helen V. Michel, based on their analysis of a global clay layer marking the K–Pg boundary. The hypothesis originated from the discovery of anomalously high concentrations of —a on but abundant in and meteorites—in the thin clay layer separating and sediments worldwide. These levels, measured at 20 to 160 times the normal crustal average, aligned precisely with the timing of the mass , suggesting an source rather than terrestrial or other gradual processes. The Alvarezes and their team estimated that an roughly 10 kilometers in diameter would have struck , vaporizing on impact and ejecting massive amounts of dust and debris into the , forming a global cloud that blocked for years and collapsed food chains by halting . Supporting evidence emerged in the early 1990s with the identification of the , a 180-kilometer-wide buried beneath the in , dated to the K–Pg boundary through , tektites, and iridium-rich ejecta matching global boundary deposits. Initially detected in the 1970s by geophysical surveys from the Mexican state oil company , the site's link to the was confirmed in 1991 by a team led by Alan R. , who correlated its melt rocks and breccias with K–Pg boundary materials found in and elsewhere. This discovery provided direct physical proof for the asteroid impact, transforming the Alvarez hypothesis from a bold proposition into the prevailing explanation for the , though debates persist on the precise mechanisms of species loss and potential contributions from Deccan volcanism.

Background

Cretaceous–Paleogene extinction event

The (K–Pg) extinction event occurred approximately 66 million years ago, defining the boundary between the period of the era and the period of the era, and representing one of the most significant mass extinctions in Earth's history. This boundary is identifiable worldwide as a thin stratigraphic layer interrupting continuous sedimentary deposits, serving as a global marker for the event's timing. The extinction was geologically rapid, unfolding over a span of mere thousands of years, and fundamentally altered the trajectory of life on the planet. The scale of the K–Pg extinction was immense, with an estimated 75% of all species on perishing, including profound losses across both terrestrial and marine realms. Prominent among the extinct groups were non-avian dinosaurs, which had dominated terrestrial ecosystems for over 150 million years; pterosaurs, the flying reptiles that ruled the skies; and marine reptiles such as mosasaurs and plesiosaurs. Many also suffered heavy attrition, with entire classes like ammonites and vanishing entirely. In contrast, survival was selective: avian birds (descended from theropod dinosaurs), small mammals, crocodilians, , and certain fish groups endured, as did a subset of including ferns, cycads, and some angiosperms that could recolonize disturbed landscapes. Leading up to the event, the world exhibited peak biodiversity, with ecosystems teeming with diverse herbivorous and carnivorous dinosaurs, the widespread dominance of flowering plants (angiosperms) that had radiated globally, and marine environments rich in , fish, and large predators. Supercontinents had fragmented into northern and southern , fostering regional while high sea levels created extensive shallow inland seas that boosted coastal habitats. The climate was notably warmer than today, with tropical to subtropical conditions extending to higher latitudes, minimal polar ice, and elevated atmospheric CO₂ levels supporting lush vegetation and proliferation. Paleontologists first noted the abrupt faunal turnover at the K–Pg boundary in the early , observing sharp discontinuities in fossil records where assemblages of ammonites, dinosaurs, and other taxa gave way suddenly to forms dominated by mammals and modern-style marine life. These initial discoveries, made through stratigraphic studies in and , highlighted the event's catastrophic nature long before its causes were understood, prompting early debates on the mechanisms driving such rapid biotic change.

Iridium anomaly discovery

The iridium anomaly was first identified in the late 1970s through detailed geochemical analysis of sediment cores from the Cretaceous–Paleogene (K–Pg) boundary, a stratigraphic layer marking the mass extinction event approximately 66 million years ago. In the Gubbio section of Italy, researchers measured iridium concentrations reaching up to 9.1 parts per billion (ppb) in the boundary layer, representing an enrichment of about 30 times above background levels of approximately 0.3 ppb in surrounding Upper Cretaceous sediments. Similar analyses in Denmark's Stevns Klint section revealed even higher values, with up to 29 ppb in whole-rock samples and 65 ppb in acid-insoluble residues, indicating an enrichment factor of around 160 times the background. These findings, based on neutron activation analysis of multiple samples, highlighted a sharp spike in iridium precisely at the K–Pg boundary, contrasting with stable low levels in pre- and post-boundary strata. Iridium's extreme rarity in Earth's , where it occurs at concentrations below 0.1 ppb, contrasted sharply with its relative abundance in , such as carbonaceous chondrites (around 500 ppb), prompting inferences of a massive influx. This siderophile , typically concentrated in Earth's due to its affinity for iron during , is depleted in the crust but enriched in meteorites and asteroids, making the anomaly's magnitude—30 to 160 times background—a key indicator of cosmic delivery. Early quantifications established global iridium levels in the boundary layer averaging 20–30 ppb, far exceeding terrestrial norms and suggesting a singular, planet-wide deposition event. The spike is embedded within a distinctive boundary clay layer, typically 1–2 cm thick at but up to 35 cm in , composed of fine-grained, carbonate-free clay enriched in clay minerals and lacking primary biogenic structures. This layer exhibits global distribution, appearing in marine and terrestrial sections across , , , and beyond, with consistent enrichment despite variations in thickness and local sedimentation rates. Compositionally, the clay includes impact-derived features such as grains displaying multiple sets of planar deformation features—hallmarks of high-pressure shock metamorphism—and microtektites, small (under 1 mm) glassy spherules formed from impact melting, both concentrated at the boundary and absent elsewhere in the stratigraphic record.

Hypothesis Development

Alvarez research origins

Luis Walter Alvarez (1911–1988) was a renowned and Nobel laureate who made seminal contributions to physics, including the discovery of numerous resonance states using the technique at the . His expertise in and instrumentation, honed during his career at the , where he joined in 1936 and became a full in 1945, later extended to interdisciplinary applications such as geochemical analysis. Walter Alvarez, born in 1940, is a and in the Department of Earth and Planetary Science at UC Berkeley, with research focused on , , and the role of asteroid impacts in Earth history; he earned his Ph.D. from in 1967 and joined Berkeley's faculty in 1972, becoming an assistant in 1977. The collaboration between father and son began in the 1970s at UC Berkeley, initially centered on paleomagnetic studies of magnetic field reversals in rock sequences, before shifting to the puzzle of mass extinctions at the Cretaceous–Paleogene (K–Pg) boundary. Walter's fieldwork in the Italian Apennines during the mid-1970s, examining pelagic limestone sequences for evidence of tectonic processes, revealed a striking abrupt decline in the abundance and diversity of calcareous planktonic foraminifera across the K–Pg boundary, prompting questions about the causes of this sudden biotic turnover. Luis, intrigued by the mechanisms of mass extinctions and seeking precise chronological markers, proposed applying his particle physics techniques to geology, suggesting the use of iridium—a rare element on Earth's crust but abundant in meteorites—as a potential tracer for extraterrestrial material or supernova events. In 1977, conducted targeted sampling at the classic K–Pg boundary section near , , in the Bottaccione Gorge, where he collected limestone and clay samples spanning the to investigate the foraminiferal turnover. These samples were analyzed using (NAA), a sensitive radiochemical technique developed in Luis's nuclear physics lab and performed by collaborators Frank Asaro and Helen V. Michel at Berkeley Lab; preliminary results were reported in 1979, revealing an iridium concentration in the boundary clay of approximately 6 —about 30 times higher than in the adjacent limestones (typically ~0.3 ppb). To determine if this iridium enrichment was a local anomaly or a global signal, the team extended fieldwork in 1978 to the Stevns Klint section in , where NAA confirmed a similar iridium spike at the K–Pg boundary, with concentrations around 32 ppb. Drawing on these findings, the Alvarezes formulated the core of the impact hypothesis in 1979–1980, positing that the global resulted from the vaporization and atmospheric dispersal of an extraterrestrial bolide, rather than volcanic or sources, as the observed iridium flux matched the of carbonaceous chondrites. Using estimates of the budget in the , the total amount deposited worldwide (approximately 5 × 10^7 kg), and the bolide's likely density and , they calculated that a single approximately 10 km in diameter striking at cosmic velocities would eject sufficient vaporized material to account for the observed enrichment, while also triggering the climatic catastrophe leading to mass extinction. This quantitative model integrated Luis's expertise in high-energy particle interactions with Walter's stratigraphic insights, marking a pivotal interdisciplinary advance in understanding the K–Pg event.

Publication and early reception

The Alvarez hypothesis was formally announced in a seminal paper published on June 6, 1980, in the journal Science, titled "Extraterrestrial Cause for the Cretaceous-Tertiary Extinction," co-authored by physicist Luis W. Alvarez, geologist Walter Alvarez, and nuclear chemists Frank Asaro and Helen V. Michel. The authors proposed that an asteroid approximately 10 km in diameter struck Earth about 66 million years ago, vaporizing on impact and ejecting massive amounts of iridium-rich dust into the atmosphere, which caused a global "impact winter" by blocking sunlight and disrupting photosynthesis. This mechanism, they argued, explained the observed iridium enrichment at the Cretaceous-Tertiary (K-T) boundary and the abrupt extinction of approximately 75% of Earth's species, including non-avian dinosaurs. The publication elicited a polarized initial response within the scientific community. Geochemists and astronomers lauded the hypothesis for its elegant integration of the with extraterrestrial sourcing, viewing it as a breakthrough in explaining the boundary's geochemical signatures. However, many paleontologists and traditional geologists met it with strong , arguing that patterns suggested more gradual processes like sea-level changes or rather than a singular catastrophic event, and dismissing the idea as overly speculative. Beyond academia, the hypothesis captured widespread attention, often dramatized as the "dinosaur killer" scenario in newspapers, television broadcasts, and radio programs throughout the early , amplifying public fascination but sometimes oversimplifying the nuanced scientific claims. Early scientific debates intensified in 1981, with discussions at conferences highlighting tensions over potential periodicity in mass extinctions—suggesting recurring cycles incompatible with a one-off impact—and the role of multiple causal factors like alongside any event. These exchanges underscored disciplinary divides, as paleontologists emphasized record selectivity while proponents focused on geochemical uniformity. By the mid-1980s, acceptance grew as anomalies were confirmed at over 50 K-T boundary sites worldwide, from deep-sea cores to terrestrial outcrops, reinforcing the global scale of the event and bolstering the impact model's credibility among a broader consensus of scientists. This accumulation of prompted a shift from outright rejection to qualified endorsement, though debates on selectivity persisted.

Supporting Evidence

Geochemical signatures

The provided the initial geochemical clue suggesting an impact at the K–Pg boundary. isotope ratios in the boundary clay exhibit low values of 187Os/188Os ≈ 0.15, markedly lower than typical crustal ratios of ~1.0, which points to a chondritic source for the material. This excursion in osmium isotopes is globally consistent across and terrestrial sections, reflecting the rapid influx of osmium that overwhelmed the radiogenic signature of . Enrichments in platinum-group elements (PGEs) at the K–Pg boundary display concentration patterns and inter-element ratios that closely match those in carbonaceous chondrites rather than terrestrial sources. These PGE signatures, including elevated levels of , , and alongside , confirm the chondritic composition of the impactor and distinguish it from volcanic or crustal contributions. Global carbon and oxygen isotope excursions mark the boundary, with a negative δ13C shift of ~1–2‰ in marine carbonates and organic matter signaling the injection of 13C-depleted CO2 from biomass burning and vaporized organic-rich sediments. Concurrently, a positive δ18O excursion of ~1‰ indicates transient global cooling due to sulfate aerosols and dust from the impact. Soot and charcoal abundance in boundary layers, reaching up to 0.2–0.4% by weight in some sections, evidences widespread wildfires ignited by the impact's .

Impact crater identification

In the early , geophysical surveys utilizing and magnetic data from revealed a large, buried circular approximately 180 km in diameter off the northern coast of the in , centered near the town of Chicxulub. These , characterized by a central positive surrounded by a semicircular negative anomaly, were first interpreted as of an in a seminal 1991 study that linked the feature to the Cretaceous–Paleogene (K–Pg) . Subsequent seismic surveys in 1996 further delineated the subsurface , confirming its through distinct stratigraphic disruptions and variations consistent with shock metamorphism. Confirmation of the crater's nature came from core samples retrieved from oil exploration wells in 1991, particularly the Yucatán-6 borehole, which contained grains exhibiting multiple sets of planar deformation features indicative of high-pressure shock waves exceeding 5–10 GPa. These samples also included melt breccias and suevite-like rocks with fragmented basement material embedded in a glassy matrix, providing direct evidence of hypervelocity melting. Argon-argon (⁴⁰Ar/³⁹Ar) dating of the melt rock from these wells yielded an age of approximately 66.0 ± 0.04 million years ago, precisely coeval with the K–Pg boundary and iridium-rich layers observed globally. The morphology of the , as imaged by seismic data, features a well-preserved basin with a central structural uplift collapsed into a ~80 km diameter ring of fault-bounded peaks, surrounded by a terrace zone and an outer rim. This configuration matches numerical models of large terrestrial impacts, where the transient cavity collapses to form inward-directed faults and an blanket distributed asymmetrically due to the low-angle impact trajectory. The crater's dimensions and internal structure thus align with predictions for a capable of producing the observed global K–Pg geochemical signatures, such as elevated levels. Analysis of trace elements in tektites and impact glasses from the crater indicates that the impactor was likely a carbonaceous chondrite, with elevated levels of siderophile elements like ruthenium showing isotopic ratios matching those of outer solar system asteroids formed beyond Jupiter's orbit. This composition is consistent with the projectile's role in delivering the iridium anomaly and other platinum-group elements to the K–Pg boundary clay.

Paleontological correlations

Paleontological evidence strongly supports the Alvarez hypothesis by demonstrating patterns of abrupt turnover and selective survivorship in the fossil record that align with the predicted effects of a global at the (K–Pg) boundary. Non-avian fossils cease entirely above the K–Pg boundary layer worldwide, marking a sudden halt in their presence after millions of years of dominance, which indicates a catastrophic disruption incompatible with gradual environmental changes. This sharp cutoff is observed in multiple formations, such as the in , where diverse dinosaur assemblages give way to Paleogene deposits lacking them. A key biological signature is the "fern spike" in pollen and spore records immediately overlying the boundary clay, where fern spores comprise up to 90% of the palynoflora, far exceeding pre-boundary levels dominated by gymnosperms and angiosperms. This anomaly reflects the devastation of higher plant communities, likely due to impact-induced wildfires, dust loading, and sunlight blockage, leading to and the opportunistic proliferation of resilient, spore-dispersing as . The spike is documented globally at over 100 sites, underscoring its role as a marker of rapid terrestrial recovery following near-total floral disruption. Survivorship patterns among terrestrial vertebrates highlight traits that buffered against the impact's aftermath, particularly for mammals. Pre-boundary mammals were predominantly small (<1 kg body mass), with many exhibiting burrowing behaviors or omnivorous diets that included seeds, fruits, and —adaptations that enabled access to stored food and during prolonged and . Insectivorous and seed-eating lineages, such as multituberculates and early placentals, show higher survival rates compared to larger or specialized herbivores, facilitating their diversification in the . These selective pressures align with modeled post-impact conditions of reduced primary productivity. In marine environments, the K–Pg boundary records extreme turnover in microfossils, with over 90% of planktonic foraminiferal extinct, primarily affecting larger, photosymbiotic, and tropical taxa. Survivors were typically small, nonsymbiotic, and opportunistic forms that underwent significant size reductions (up to 50% in test diameter), reflecting to darkened, nutrient-stressed oceans with collapsed webs. This selective extinction, observed in deep-sea cores worldwide, points to a rapid oceanic crisis triggered by the impact's atmospheric and climatic effects. Exceptional preservation at the site in captures the immediate biological fallout, with fossilized and containing impact spherules embedded in their gills and , evidencing direct exposure to the cloud. Seasonal growth rings in these otoliths and scales, combined with burrowing annuli, indicate the event occurred in boreal spring, with organism death within hours of the Chicxulub impact approximately 3,000 km away. This temporal precision confirms the synchrony of the mass die-off with the asteroid strike.

Ongoing Research

Chicxulub crater expeditions

The , identified as the primary impact structure linked to the event, has been explored through targeted drilling and geophysical expeditions to elucidate the mechanics of the collision and its immediate aftermath. The landmark 2016 (IODP) and International Continental Scientific Drilling Program (ICDP) Expedition 364 penetrated the crater's via borehole M0077A, situated approximately 30 km offshore the in the . This mission recovered a continuous 829-meter core from depths of 505 to 1335 meters below seafloor, exposing shocked granitic basement rocks bearing planar deformation features and other shock metamorphism signatures consistent with pressures exceeding 5-10 GPa during the impact. The cores also documented pervasive hydrothermal alteration, including veining with clays, zeolites, and sulfides, indicating prolonged fluid circulation driven by residual impact heat that persisted for up to 150,000 years post-impact. Core examinations further highlighted the role of gypsum dehydration in the impact dynamics, as the collision vaporized sulfate-bearing evaporites from the target sedimentary sequence, releasing sulfur dioxide gas—estimated at 67 ± 39 gigatons based on 2025 empirical analyses—that rapidly formed stratospheric . This aerosol loading resulted in a notable but less severe reduction in solar radiation and compared to prior models, contributing to the "" and inhibition of . Subsequent 2020s investigations built on Expedition 364 samples with integrated seismic reflection surveys and hydrocode simulations, enhancing resolution of the 's subsurface architecture, including the transient cavity collapse and uplift. These analyses corroborated an impactor velocity of 12-20 km/s at a low angle (45-60° from horizontal), aligning with the observed ~200 km diameter and asymmetric distribution. Efforts to drill Chicxulub originated with conceptual proposals in the early under ICDP auspices, evolving through feasibility studies and campaigns that secured the 2016 operation after nearly a decade of preparation. Data from the expedition continue to yield insights, with 2023 analyses of microbiomes revealing diverse communities of sulfate-reducing and other extremophiles shaped by the post-impact hydrothermal system, with evidence of microbial activity established during the ~150,000-year cooling phase, underscoring the crater's potential as a habitable niche amid global devastation. A 2025 study further indicates that the hydrothermal system facilitated rapid recovery of at the impact site, supporting microbial and faunal recolonization in the aftermath.

Global ejecta and tsunami studies

The global distribution of from the Chicxulub includes layers of impact spherules and tektite-like glasses found across continents such as , , and , forming a thin but widespread stratigraphic marker at the K-Pg boundary. These materials, primarily composed of shocked minerals and molten droplets quenched into spherules, decrease in thickness and with distance from the site, reflecting ballistic dispersal and atmospheric re-entry. In sites, such as those in , layers reach 1–2 cm in thickness, containing abundant microspherules up to 1 mm in diameter that are enriched in siderophile elements. Evidence for mega-tsunamis generated by the impact comes from coarse-grained deposits in coastal settings around the . A 2018 modeling and field study reconstructed initial wave heights exceeding 1.5 km near the crater, with run-up heights of 100–300 m documented in onshore deposits in and through analysis of boulder fields, rip-up clasts, and hummocky cross-stratification in the K-Pg event beds. These deposits, often several meters thick and containing mixed and terrestrial debris, indicate multiple wave pulses that inundated up to 300 km inland, scouring and redepositing sediments in chaotic layers. Refined from a 2022 study combined isotope analysis of impact ejecta with examination of annual growth increments in otoliths embedded in boundary sediments, pinpointing the timing to spring in the . The ratios in glass provided precise dating, while incomplete growth rings in otoliths from sites indicated interrupted seasonal development consistent with a boreal spring event, offering insights into the paleoenvironmental context of the catastrophe. Numerical modeling of dynamics demonstrates that fragments followed ballistic trajectories, reaching altitudes of hundreds of kilometers before re-entering the atmosphere at velocities up to 10 km/s, generating fluxes sufficient to ignite widespread firestorms. This re-entry heating, estimated at 10–100 kW/m² over large areas, is corroborated by elevated influx and particles in global K-Pg boundary sections, indicating biomass burning that contributed to atmospheric darkening and short-term cooling. The serves as the confirmed source for these patterns. Recent 2025 research on contributions suggests these firestorms and effects, combined with milder cooling, played a key role in the mass extinction dynamics.

Criticisms and Alternatives

Challenges to the impact model

Earlier analyses, such as those of the Yaxcopoil-1 core drilled within the , suggested a potential timing discrepancy, with diverse and well-preserved assemblages of late planktic in the lowermost 16 meters interpreted as indicating normal marine sedimentation and biotic conditions for approximately 300,000 years after the impact, implying it predated the K-Pg boundary by at least 200,000–300,000 years and lacking associated deposits or coarse-grained layers. However, high-precision has since confirmed that the Chicxulub impact occurred synchronously with the K-Pg boundary at approximately 66.04 Ma, resolving this apparent gap and aligning the event with the mass extinction. Critiques of the impact model's selectivity highlight inconsistencies in why certain ecologically similar groups survived while others perished, undermining the universality of a single global catastrophe. For instance, crocodilians, which share ectothermic metabolisms and semi-aquatic habitats with extinct marine reptiles like mosasaurs and plesiosaurs, exhibited high survival rates across the K-Pg boundary, with approximately 50% of crocodyliform species persisting despite comparable vulnerabilities to environmental disruption. In contrast, large marine reptiles underwent near-total extinction, even though the impact's proposed effects—such as ocean acidification and productivity collapse—should have affected both groups similarly. This differential survival pattern, observed in both terrestrial and marine realms, suggests that factors beyond a singular bolide strike, including pre-existing ecological stresses or habitat refugia, played a role, as the model struggles to explain why small, burrowing reptiles thrived while larger dinosaurs with analogous traits did not. The of multiple impacts contemporaneous with the K-Pg further complicates the single-impact framework of the Alvarez model. Seismic data from the offshore West African , a 8.5–9.2 km-wide structure, indicate formation approximately 66 million years ago, aligning closely with the Chicxulub and the horizon. Three-dimensional imaging confirms impact features such as a central uplift and disrupted , suggesting a fragmented or swarm delivered at least two large bolides within a short timeframe, potentially amplifying environmental perturbations like distribution and atmospheric loading. Although dated within error margins of the K-Pg , this evidence challenges the exclusivity of Chicxulub as the sole driver, implying a clustered that the original did not anticipate. Debates over atmospheric modeling reveal potential flaws in projections of prolonged from sulfur aerosols released by the Chicxulub impact. Empirical estimates from K-Pg boundary sites, including the site, indicate a total sulfur release of 67 ± 39 gigatons (range: 28–106 Gt), significantly lower than prior numerical simulations that assumed 325 ± 130 Gt. This reduced aerosol injection would result in milder short-term cooling—potentially a "survival window" rather than years-long ""—as sulfate particles' stratospheric residence time and are overestimated in models relying on high-end vaporization scenarios. Such discrepancies question whether sulfur-driven dimming alone could sustain the decade-scale darkness and temperature drops needed to collapse global food chains, prompting reevaluations of complementary and contributions.

Volcanic eruption theories

The represent a vast in west-central , formed by massive eruptions spanning approximately 66.5 to 65.5 million years ago (Ma), during the late stage of the period. These eruptions produced an estimated 1 to 2 million cubic kilometers of basaltic lava, originally covering up to 1.5 million square kilometers, though erosion has reduced the preserved area to about 500,000 square kilometers. The volcanism occurred in pulsed phases, with the majority of the volume (around 80%) emplaced over a relatively short interval of less than 1 million years, potentially linked to a . The environmental impacts of Deccan Traps volcanism are proposed as a primary driver of the Cretaceous–Paleogene (K–Pg) mass extinction, through massive releases of volcanic gases and particulates. Elevated carbon dioxide (CO₂) emissions, estimated at 270–900 parts per million (ppm) from early phases, contributed to global greenhouse warming of up to 8°C, disrupting ecosystems and ocean chemistry. Concurrently, sulfur dioxide (SO₂) injections, reaching concentrations of up to 1,800 ppm in some lavas, led to stratospheric sulfate aerosol formation, causing short-term global cooling, acid rain, and ocean acidification. Additionally, enrichments in mercury (Hg) and halogens like fluorine (400–3,000 ppm in lavas) in marine sediments indicate widespread poisoning, with Hg anomalies correlating to biotic stress and climate shifts prior to the K–Pg boundary. Paleontologist has been a leading proponent of Deccan volcanism as the dominant cause, arguing based on foraminiferal and other records from multiple sites that marine biotic diversity declined progressively over at least 10 years before the proposed Chicxulub impact, aligning with the onset of major eruptions. Her analyses show two pulses of extinction: an initial one around 66.23 Ma affecting benthic species, tied to warming and , followed by a sharper event at the boundary. Supporting evidence includes geochemical signatures potentially attributable to volcanism, such as plume-related iridium enrichments in some sedimentary sites, though these are substantially lower (often below 0.1 ng/g) than the global impact-related anomaly of ~50 ng/cm². Negative excursions in carbon-13 isotopes (δ¹³C) in marine records, linked to massive CO₂ outgassing, further indicate volcanic disruption of the preceding the extinction peak. Some researchers have suggested that the itself could partly stem from volcanic sources, though this remains debated.

Combined hypotheses

In the decades following the initial formulation of the Alvarez hypothesis, researchers have developed integrative models that combine the Chicxulub asteroid impact with volcanism to explain the Cretaceous-Paleogene (K-Pg) mass , positing that neither event alone fully accounts for the observed biotic turnover. These combined hypotheses emphasize synergistic effects, where the impact delivers acute environmental perturbations while volcanism imposes sustained climatic stress, leading to a more comprehensive causal framework. A prominent example is the 2010s model proposed by geologists at the , which suggests that the Chicxulub impact triggered or intensified the largest phase of Deccan eruptions through seismic wave propagation. According to this , the impact generated ground motions with seismic energy densities of 0.1–1.0 J/m³ at the Deccan site, approximately 13,000 km away, potentially increasing the permeability of the underlying magmatic system or dynamically perturbing the mantle plume feeding the eruptions. This mechanism could explain an observed acceleration in eruption rates, with modeling indicating that such shaking might have facilitated magma ascent by fracturing crustal pathways or destabilizing the plume head. Supporting the temporal overlap required for such triggering, high-precision has established between the major Deccan eruptive pulse and the Chicxulub at approximately 66 . Uranium-lead (U-Pb) dating of zircons from Deccan intertrappean beds reveals that the voluminous Wai Subgroup flows, comprising much of the eruptive volume, initiated around 250,000 years before the K-Pg boundary but peaked concurrently with the dated to 66.043 ± 0.043 . Complementary ⁴⁰Ar/³⁹Ar analyses of basaltic flows confirm this alignment, showing that ~75–80% of the Deccan volume erupted within ±100,000 years of the boundary, consistent with -induced . Within this multi-cause framework, the impact is invoked for immediate disruptions such as global dust loading, wildfires, and short-term cooling that halted , while Deccan contributed prolonged , , and toxicity over millennia. Geochemical records from K-Pg boundary sections bolster this view, revealing mixed signals including spikes from the impactor alongside mercury and enrichments indicative of volcanic . For instance, sediments at sites like , , and Caravaca, , show overlapping anomalies of extraterrestrial (up to 28 ppb) and volcanogenic mercury (up to 200 ppb), suggesting concurrent delivery of stressors that amplified pressures across marine and terrestrial realms. Recent syntheses reflect a growing among paleontologists and geochemists toward these combined effects, with multiple studies in the 2020s highlighting how the interplay of acute and chronic volcanic forcing better explains the selective patterns observed. This integrative perspective has gained traction through interdisciplinary , underscoring the rarity of such dual mega-events in Earth's .