Fact-checked by Grok 2 weeks ago

Radiolarite

Radiolarite is a fine-grained, siliceous formed predominantly from the accumulation and of microscopic silica skeletons, known as tests, from radiolarians—single-celled planktonic protists that inhabit upper waters. These tests, ranging from 0.1 to 1 mm in size with most around 0.1–0.2 mm, settle on the seafloor in nutrient-rich, low-sediment deep- environments, creating layers of biogenic silica ooze that undergo , compaction, and silicification to form the rock. Unlike denser cherts, radiolarite often retains a more porous, less cemented structure with abundant remains visible under magnification. The formation of radiolarite occurs primarily in deep-marine settings, such as abyssal plains or subduction-related basins, where currents supply silica and nutrients to support prolific radiolarian blooms. Compositionally, it consists mainly of microcrystalline or (60–97% silica), with minor impurities including clay minerals, , iron oxides, and trace elements that impart various colors. Geologically, radiolarite preserves radiolarian microfossils useful for and paleoceanographic reconstructions, particularly in and sequences. It is associated with complexes and volcanic rocks, reflecting deposition at depths of 1,000–4,000 meters. Notable occurrences include the Franciscan Complex in (ribbon cherts ~100–200 million years old) and Tethyan sequences in the and Mediterranean region. While not significant for large-scale extraction, radiolarite was used historically for stone tools due to its hardness and flaking properties, with modern applications in research and ornamentation.

Definition and Composition

Mineralogical Composition

Radiolarite is primarily composed of quartz, often in the form of , which constitutes 90-100% of the rock and originates from the biogenic opal-A skeletons of radiolarians. The dominant silica phase in mature radiolarite is , representing the final stage of diagenetic transformation from initial amorphous opal-A (biogenic silica) through intermediate opal-CT (characterized by leisphere structures) to quartz. Minor components make up up to 10% of the rock and include clay minerals such as and , carbonates like and , and iron oxides (e.g., ), which contribute to color variations ranging from white to red-black. Accessory phases may include , , and . The chemical formula of the dominant phase is SiO₂ (), with trace elements such as , Fe, and Mg incorporated from associated sediments, reflected in compositions showing SiO₂ contents of 66-98%, Al₂O₃ (0.8-15%), and Fe₂O₃ (0.15-8%). Radiolarite exhibits a specific of 2.4-2.6 g/cm³ and a Mohs of 6.5-7, properties that distinguish it from purer chert variants due to its siliceous, microcrystalline fabric.

Petrological Characteristics

Radiolarite is classified as a fine-grained, thinly bedded siliceous sedimentary rock, primarily biogenic in origin and often regarded as a subtype of chert, but distinguished by its composition exceeding 50% silica derived from radiolarian skeletons. It forms a non-clastic rock type with silica content typically ranging from 60% to 90%, dominated by opaline silica that recrystallizes into microcrystalline quartz or chalcedony during diagenesis. Macroscopically, radiolarite exhibits a hard, brittle with a , resembling chert in its compactness and glassy luster. is characteristically thin, with layers measuring 1 to 10 in thickness, and the rock displays a range of colors including white or gray for purer silica varieties, and red or brown hues imparted by oxidized iron oxides. These features make it identifiable in hand samples as a dense, smooth material often showing subtle intricate patterns from preserved skeletal structures. At the , radiolarite consists of a matrix of or embedding molds, pseudomorphs, or remnants of radiolarian tests, which range from 0.1 to 0.5 mm in diameter. The fabric is microgranular, with fibrous aggregates filling skeletal voids, and post-diagenetic is low due to the tight structure. Radiolarite differs from other cherts in its elevated biogenic silica content, with radiolarian-derived components comprising the majority, as opposed to higher proportions of detrital or inorganic precipitates in non-biogenic cherts. It commonly occurs in bedded forms but can also appear nodular, with the presence of molds providing a key diagnostic trait absent or minor in typical cherts. Physically, radiolarite demonstrates low permeability due to its tight structure and possesses high , which underscores its and to . These properties facilitate its recognition in the field and its use as an indicator of siliceous sedimentary environments.

Formation Processes

Biological Sedimentation

Radiolarians are planktonic protists characterized by intricate siliceous tests, serving as major contributors to biogenic silica and , accounting for 14–31% of total biogenic silica flux in modern oceans. These single-celled organisms thrive primarily in the euphotic , from the surface to approximately 200 m depth, where light penetration supports associated photosynthetic symbionts and availability drives their abundance. As key silica cyclers, radiolarians precipitate amorphous silica () into their tests, facilitating the transfer of silica from dissolved forms in to that influences global biogeochemical cycles. The of radiolarian skeletons begins with their post-mortem sinking from surface waters to the seafloor, occurring at rates ranging from 13 to 416 m per day depending on test size, weight, and . For a typical pelagic of 5 km depth, this results in transit times of 2 weeks to 14 months, during which significant can occur in undersaturated deep waters, particularly for fragile phaeodarian tests, though polycystine skeletons often preserve with minimal loss upon reaching the sediment-water interface. Only a small fraction of produced tests ultimately contribute to sediments due to this and biological reworking, emphasizing the inefficiency of silica transfer in the . Radiolarian productivity and subsequent are closely linked to environmental conditions promoting blooms, such as of nutrient-rich waters that enhance silica availability and planktonic growth. In modern analogs, biogenic silica fluxes from radiolarians range from approximately 0.01 to 0.1 g/m²/year in polar regions, with higher values in equatorial zones reflecting pulsed deposition events. These blooms often occur seasonally or episodically, as seen in Tethyan settings where monsoon-driven triggered enhanced radiolarian proliferation and silica input. The initial deposit formed by settling radiolarian tests is a loose, uncompacted ooze, or radiolarian mud, comprising 20–50% biogenic silica alongside minor fractions of clay minerals and carbonates from admixed pelagic particles. This accumulates in low-sedimentation-rate environments, preserving the fragile tests before any subsequent alteration.

Diagenetic Evolution

The diagenetic evolution of radiolarite involves the progressive transformation of biogenic opal-A, derived from the silica skeletons of radiolarians, into more stable mineral phases through and recrystallization under increasing conditions. This process commences shortly after deposition of on the seafloor and unfolds in distinct stages: initial and recrystallization of opal-A to opal-CT (a mixture of and ) typically occurs at depths of approximately 40-500 meters, followed by the conversion of opal-CT to at greater depths (e.g., >300 meters in some settings) or s of 40-60°C. These phase transitions are driven primarily by escalating and with , coupled with silica in fluids; variations in pH and fluid chemistry, such as or magnesium content, further modulate the of these changes by influencing silica and rates. Associated with these transformations is widespread cementation by authigenic silica, which progressively seals intergranular spaces and reduces initial porosity of the unconsolidated ooze from 60-80% to less than 5% in mature radiolarite, enhancing lithification and mechanical strength. Minor dolomitization or additional silicification may affect adjacent carbonate-rich or clayey sediments through diffusive transport of silica from the ooze, though these are secondary to the primary silica phases within the radiolarite itself. The entire sequence spans millions of years, with full conversion to quartzose radiolarite often requiring 30-50 million years of burial, consistent with observations in Cretaceous to Paleogene sequences; for instance, Jurassic radiolarites achieve complete quartz transformation after this duration under typical pelagic sedimentation rates. Evidence for these diagenetic alterations is derived from X-ray diffraction () analyses, which reveal progressive shifts in silica crystallinity, such as broadening or sharpening of d-spacing peaks (e.g., 4.04-4.12 Å for opal-CT), confirming the opal-A to opal-CT to sequence. Isotopic signatures further document the overprint, with oxygen isotopes (δ¹⁸O) exhibiting intra-sample variability of 0.16-2.49‰ in radiolarites, indicative of incomplete homogenization during phase transitions and fluid interactions, while isotopes (δ³⁰Si) show patterns (e.g., -0.6‰ to 2.6‰) reflecting kinetic effects during dissolution-reprecipitation.

Compaction and Sedimentation Rates

Compaction in radiolarite deposits primarily involves consolidation under increasing lithostatic from overlying sediments, leading to a significant volume reduction of 50-70% through the expulsion of pore fluids and rearrangement of silica skeletons. This process is quantified using -depth curves, which show an exponential decrease in from approximately 70-80% in unconsolidated radiolarian ooze to 5-15% in lithified chert, driven by the transformation of opal-A to more stable silica phases like and . The expulsion of fluids during this enhances the mechanical weakness in clay-rich layers, such as those observed in radiolarian clays on the Barbados margin. Sedimentation rates for radiolarite are characteristically low, ranging from 0.1-2 cm/kyr (1-20 m/) in deep-sea environments, reflecting the slow accumulation of biogenic silica in stable oceanic settings. For instance, in the , rates have been estimated at 7-15.5 m/ based on integrated stratigraphic analyses of radiolarite sequences in the Northern Calcareous Alps. Several factors influence these rates, including proximity to continental margins, which introduces higher clay input that dilutes biogenic silica and slows pure radiolarite accumulation, and peaks in biogenic productivity that enhance skeletal flux to the seafloor. Sedimentation rate is fundamentally calculated as thickness divided by time, but must be adjusted for compaction using the formula for decompacted thickness = observed thickness / (1 - compaction factor), where the compaction factor represents the fractional volume loss (e.g., 0.5-0.7 for 50-70% reduction). Measurement of these rates typically combines biostratigraphic dating via radiolarian zones with stratigraphic thickness assessments, providing precise chronologies for thin-bedded sequences. In ophiolite complexes, such as those in the , this approach reveals episodic thickening linked to pulsed productivity or tectonic events. Slow rates in radiolarite indicate deposition in stable, deep-water settings with minimal detrital input, while rapid rates are associated with tectonic that enhances accommodation. These patterns underscore the role of diagenetic hardening in conferring resistance to further compaction once advances.

Depositional Environment

Depth and Setting

Radiolarites primarily form in pelagic, deep-marine environments at water depths exceeding 200 meters, with typical deposition occurring between 1000 and 4000 meters. These settings are situated below the compensation depth (CCD), where dissolution limits the accumulation of sediments, allowing siliceous radiolarian oozes to dominate. However, deposition occurs above zones of extreme silica undersaturation, where intense dissolution would prevent the preservation of biogenic silica skeletons, ensuring that radiolarian tests reach the seafloor relatively intact. Exceptions to this deep-water regime are rare and typically confined to shallow-water (neritic) settings in regions of intense coastal , where nutrient-rich waters promote high radiolarian productivity despite the reduced depth. For instance, certain radiolarite deposits in southern exhibit characteristics indicative of a shallow-water origin, including associations with red shales and evidence of subaerial exposure. Such occurrences highlight localized paleoceanographic anomalies rather than the norm for radiolarite formation. Associated sedimentary often include interbedding with shales or limestones, reflecting variations in clastic or biogenic input to the deep-sea floor. Expansion of oxygen minimum zones (OMZs) in these environments enhances the preservation of and siliceous tests by limiting oxidative degradation and bioturbation. Depth indicators for radiolarite deposits include the notable absence of benthic fossils, which points to environments inhospitable to bottom-dwelling organisms, and the high purity of radiolarian skeletons within the , signifying minimal dilution by other components. Paleobathymetric reconstructions, achieved through modeling of associated tectonic basins, further confirm these deep-water conditions by accounting for post-depositional vertical movements. In terms of tectonic context, radiolarites are commonly preserved in ancient ocean basins or marginal seas such as the , where initial pelagic sedimentation gave way to tectonic deformation. Post-depositional thrusting within orogenic belts, like the Alpine-Apennine system, has since exhumed these deep-marine sequences, exposing them in mountain ranges. Sedimentation rates for radiolarites can vary with water depth, influencing the thickness and rhythmicity of deposits.

Textural Features: Banding and Ribbons

Radiolarite often exhibits distinctive rhythmic banding characterized by alternating light-colored, silica-rich layers and darker, clay-rich layers, typically ranging from 0.5 to 5 mm in thickness, reflecting variations in composition and deposition rates. These bands form due to periodic fluctuations in radiolarian productivity and terrigenous input, with the light layers dominated by nearly pure microcrystalline derived from biosiliceous ooze and the dark layers enriched in clay minerals from eolian or detrital sources. In low-energy deep-marine settings, cross-lamination is rare, but microfabrics within bands may include nodules, breccias, or mottled textures resulting from minor slumping or early diagenetic processes that preserve the original layering. A specialized variant known as ribbon radiolarite features thicker, more pronounced bands, with chert layers averaging 1-10 cm in thickness separated by thin partings (typically 1-2 cm), creating a striped or ribbon-like appearance upon . These structures arise from enhanced silica precipitation and periodic clay influx, often linked to Milankovitch-scale , such as cycles (approximately 20 kyr) that modulate seasonal silica flux from or radiolarian blooms. For instance, in Tethyan sections, of gamma-ray logs reveals (100 kyr) and signals in band spacing, implying sedimentation rates of around 10 m/m.y. and continuous deposition over millions of years. The banding serves as a diagnostic indicator of , low-sedimentation environments with minimal , as seen in Hallstatt-type sequences where over 1000 couplets record prolonged hemipelagic accumulation without significant interruption. Recent studies on Tethyan radiolarites, using high-resolution cyclostratigraphy, confirm in band formation, attributing dark layers to enhanced eolian dust input during arid climatic phases modulated by and . Diagenetic processes further enhance contrast by selective silicification of radiolarian-rich intervals, preserving the rhythmic patterns.

Stratigraphic Distribution

Paleozoic Occurrences

The earliest known occurrences of radiolarite date to the Upper Cambrian (Furongian) in Kazakhstan, where bedded to nodular cherts containing abundant radiolarian tests accumulated in deep-marine settings of the Paleo-Asian Ocean over several million years, marking the onset of biogenous siliceous sedimentation. These deposits, primarily reddish to pinkish cherts with fine-scale lamination and Mn-Fe micronodules, reflect low sedimentation rates and minimal clastic input, with SiO2 contents exceeding 96 wt% indicating a predominantly biogenic origin influenced by hydrothermal activity. Similar Upper Cambrian radiolarian-bearing cherts have been documented in South China, particularly in Hunan Province, where primitive polycystine forms appear in micritic limestones and associated siliceous facies of the Bitiao Formation, providing evidence for early radiolarian diversification in peri-Gondwanan settings. In , radiolarite occurrences expanded during the -, notably in the Rhenohercynian zone of , where dark gray to black lydites (a variety of radiolarite) formed in deep-water basins along the Avalonian margin, as seen in Silurian sequences near , . These siliceous slates, interbedded with graptolitic shales, represent pelagic sedimentation in tectonically active settings post-dating the Ordovician radiation, with radiolarian faunas showing increased diversity by the Darriwilian stage. radiolarites are prominent along the Appalachian margin in , exemplified by the Huntersville Chert in and adjacent areas, where ribbon-like cherts up to 100 m thick accumulated as radiolarian tests and sponge spicules in shallow to outer shelf environments during the . In the Uralides, radiolarites occur in the South Urals, with Lower Carboniferous cherts in the Usolka Section containing diverse assemblages that record ongoing subduction-related basin development. These radiolarite deposits are often metamorphosed due to Variscan and Uralian orogenies, preserving primitive polycystine radiolarians for , though diagenetic overprinting and low diversity limit resolution in early assemblages. Their formation ties to margin rifting and the post-Ordovician radiolarian diversification following the , reflecting enhanced pelagic productivity in expanding ocean basins. Recent discoveries in the 2020s from blocks, including deep-water cherts of the Liuchapo Formation, reveal potential early precursors to Furongian radiolarites, linking these deposits to the proto-Tethys opening and early subduction dynamics along the margin.

Mesozoic Occurrences

Radiolarite deposition reached its peak abundance during the era, particularly in the to periods within the Tethyan realm, including the and , and extending into the in the , such as in the Franciscan Complex of . This temporal distribution reflects enhanced siliceous productivity in expanding oceanic basins, with widespread bedded cherts forming as primary sedimentary layers overlying mid-oceanic basalts. Key occurrences include thick Triassic sequences in the , where radiolarite-bearing units reach up to several hundred meters in thickness within the broader Triassic-Jurassic succession, and Jurassic radiolarites in the Hawasina nappes of , representing deep-water pelagic deposits. In the , radiolarites are preserved in ophiolitic suture zones like the , indicating Tethyan margin sedimentation. examples are prominent in the Pacific, notably the Miyama Formation in , which contains bedded radiolarian cherts, and the Franciscan Complex in , where bedded cherts span from to , intruded by gabbroic sills and later metamorphosed. These deposits are closely linked to tectonic processes, including the spreading of the Neo-Tethys Ocean, which initiated platform drowning and radiolarite deposition as early as the Late Anisian, and -driven that boosted surface fertility along Tethyan margins. The 2014 study on influences, later extended in analyses of variations, highlights how seasonal enhanced nutrient , leading to high radiolarian over basins spanning more than 3000 km from the to . Biostratigraphically, radiolarites host diverse assemblages of nassellarians and spumellarians, with spumellarians often dominant. For instance, 2025 research on the Shiquanhe in NW documents exceptionally diverse assemblages, including 83 species across 51 genera such as Acaeniotyle, Dicerosaturnalis, and Emiluvia, confirming a mature oceanic setting no older than late . Radiolarites occur as widespread bedded cherts, with accumulation rates varying from 4 to 22 g cm⁻² × 10⁻³ yr, and serve as indicators of anoxic events, such as the , where the Radiolarian Event involved faunal turnover, size reduction, and deposition of black cherts with nodules in southwestern . In examples, these cherts often exhibit banding patterns reflective of rhythmic .

Cenozoic Occurrences

Radiolarite deposits in the era are less abundant compared to earlier periods, primarily occurring in association with closing ocean basins and tectonic uplifts. In the , significant occurrences are documented within the accretionary , where radiolarian-rich sediments, including cherty layers, formed part of the accreted oceanic materials from the Atlantic subduction zone. These deposits reflect the incorporation of deep-sea oozes into the during early convergence. Similarly, radiolarites appear in the Mediterranean region, particularly in , where () biosiliceous sediments contain radiolarian assemblages interbedded with diatomites, indicative of fluctuating silica availability in a restricted . In the , radiolarian oozes contributed to siliceous sediment accumulations, though lithification into distinct radiolarite is limited. Key examples include the late Eocene siliceous marine deposits at , which preserve radiolarian faunas in cherty facies, marking a transition from radiolarian dominance to mixed assemblages. In , radiolarian-bearing cherts occur as remnants of the closing Tethys, often within tectonic mélanges associated with arc-continent collision. These formations highlight localized preservation of siliceous oozes amid regional tectonic activity. The evolutionary context of these occurrences ties to post- recovery of radiolarian lineages following the K-Pg extinction, with Paleocene-Eocene diversification enabling renewed silica in deep-water settings. This recovery is evident in Tethyan sequences, where radiolarian records the transition from oceanic subduction to continental collision. Furthermore, the India-Asia collision around 50 Ma uplifted Tethyan remnants, exposing radiolarian cherts in the Himalaya that were deposited prior to but preserved through tectonics. Recent datasets enhance understanding of these distributions; the 2021 Southern Ocean Radiolarian (SO-RAD) dataset compiles census data from surface sediments, providing modern analogs for siliceous accumulations and revealing radiolarian diversity patterns linked to ocean circulation. Similarly, 2025 proxy studies in the Northwest Pacific utilize radiolarian microfossils to reconstruct paleoceanography, emphasizing their role in tracing silica flux changes. Overall, radiolarite exhibits a declining trend due to evolving silica cycling, with increased competition from diatoms reducing radiolarian contributions to deep-sea sediments; as a result, occurrences are rarer than in the and frequently mixed with diatom-rich layers.

Significance and Uses

Paleoenvironmental and Biostratigraphic Applications

Radiolarites, formed from the siliceous skeletons of ancient radiolarians, provide critical biostratigraphic tools through zonal schemes based on the evolutionary succession of radiolarian species, enabling precise dating of and deep-marine sequences. In the Upper , such schemes have been refined in Tethyan regions of , with recent advances incorporating high-latitude taxa to calibrate Albian-Santonian intervals against global events like oceanic anoxic episodes. For instance, 2020s taxonomic progress on Late polycystine radiolarians from northern high-latitude sections has enhanced zonal resolution, facilitating correlations across the Tethys and beyond. In paleoecological reconstructions, radiolarites serve as proxies for ancient productivity, intensity, and anoxic conditions, reflecting radiolarian blooms in nutrient-rich waters. High abundances of certain radiolarian taxa in radiolaritic beds indicate enhanced primary productivity driven by coastal or equatorial systems, as seen in analogs from the region where radiolarian fluxes correlate with organic carbon accumulation. Additionally, interbedded carbonates within radiolarite sequences yield δ¹³C and δ¹⁸O values that trace ocean chemistry fluctuations, such as carbon cycling perturbations during recovery phases, where negative δ¹³C excursions align with radiolarian diversification post-extinction. Radiolarites offer oceanographic insights into (CCD) variations and paleomonsoon dynamics in the , where their deposition below the CCD preserved silica amid carbonate dissolution. A study links Tethyan radiolarite formation to monsoon-induced , with seasonal winds promoting siliceous productivity in the northwestern Tethys during the , as evidenced by rhythmic bedding in Jurassic-Cretaceous cherts. Modern analogs from the , via the SO-RAD dataset of 2021, calibrate radiolarian assemblages to contemporary and circulation patterns, aiding interpretations of ancient CCD shoaling during Eocene-Oligocene transitions. Recent research highlights radiolarites' role in Neo-Tethys evolution, with 2025 analyses of the Duobeng Formation in the Tethys Himalaya revealing radiolarian faunas that document and basin deepening prior to India-Asia collision. A 2025 review of Northwest Pacific radiolarian microfossils further reconstructs past sea-surface temperatures, using species distributions to infer past circulation changes, including Pliocene-Pleistocene periods, with error margins of ±1.4°C. Despite these applications, radiolarite interpretations face limitations from diagenetic , where early precipitation and isotopic homogenization alter primary signals in siliceous tests, potentially biasing proxies. To achieve high-resolution dating, integration with foraminiferal is essential, as combined radiolarian-planktonic schemes resolve Permian-Triassic boundaries and Albian-Cenomanian transitions where single-group records falter due to preservation biases.

Economic and Cultural Uses

Radiolarite's exceptional hardness and properties have made it a preferred for prehistoric , enabling the production of sharp-edged tools such as axes, blades, arrowheads, and scrapers. In , extensive open-cast occurred at the Gemeindeberg site in the Vienna Basin, , during the 5th millennium BC, where radiolarite nodules were extracted and initially knapped into flakes and tools for local settlements, with waste heaps indicating large-scale operations spanning multiple mining pits. In the , radiolarite from sources like Val di Non in and Monti Lessini was widely exploited from the through the Copper Age for polished and chipped tools, including axes and bifacial daggers, often transported over distances exceeding 300 km in regional exchange networks that underscored its economic value in prehistoric societies. During the Copper Age in , quarry-workshops at La Pietra in systematically extracted radiolarite for refined armatures like arrow and javelin heads, demonstrating advanced techniques adapted to the rock's fine-grained texture. Similarly, in northern Spain's , radiolarite from and formations served as a primary knappable for diverse tools across Palaeolithic, , and protohistoric periods, with its availability in distinct varieties facilitating mobility studies among prehistoric groups. In modern contexts, radiolarite's high silica content (typically 60-90%) supports limited industrial applications, primarily as a supplementary source for silica in and ceramics manufacturing, though it is overshadowed by more abundant quartz-based materials. Certain aesthetically banded varieties have been utilized as dimension stone for decorative elements, such as countertops, tiles, and ornamental facings, particularly in regions with accessible outcrops. Culturally, radiolarite artifacts hold significant value as windows into and mobility, with Copper Age tools from sites like La Pietra preserved in museums, where they illustrate the transition to societies. Upper Palaeolithic examples, such as those from sourced from the Pieniny Klippen Belt, further highlight long-distance procurement networks in , with over 100 km transport distances evidenced in assemblages.

References

  1. [1]
    Radiolarite : Formation, Composition, Properties - Geology Science
    Nov 24, 2023 · Radiolarite is a type of sedimentary rock that primarily consists of the microscopic remains of radiolarians, which are single-celled marine microorganisms.
  2. [2]
    [PDF] Data of Geochemistry
    Diatomite, radiolarite, and spiculite are rocks that consist largely of diatom f rustules, radiolarian tests, or sponge spicules, but do not exhibit the ...
  3. [3]
    Chert FAQ - Golden Gate - National Park Service
    Sep 30, 2025 · Chert is a sedimentary rock rich in silica. Franciscan chert is formed from the tiny silica shells (0.5-1 mm) of marine plankton called Radiolaria.
  4. [4]
    [PDF] 3. silicification of deep-sea sediments and the oxygen isotope ...
    The term "radiolarite," in its most general use by geologists, could be used to describe almost all of the siliceous rocks recovered during. Leg 129. ODP ...
  5. [5]
    Geology Dictionary - Rhyolite, Rock Cycle
    Radiolarite is a sedimentary rock that forms from the accumulation of microscopic radiolarian tests and is thus of organic origin. Some geologists also ...<|control11|><|separator|>
  6. [6]
    [PDF] GEOCHEMISTRY OF TRIASSIC RADIOLARIAN CHERTS IN ... - SAV
    Preserved radiolarian tests are filled up with microcrystalline quartz and radial chalcedony. Acces- sory minerals are rounded zircon, opaque mineral grains ...
  7. [7]
    Fossilization of radiolarian skeletons | Paleontological Journal
    Jan 7, 2015 · Transformation of opal A into opal CT and quartz is under control of temperature and time. ... It is shown that, in the radiolarian skeleton, ...Missing: radiolarite | Show results with:radiolarite
  8. [8]
    Astronomical pacing of the global silica cycle recorded in Mesozoic ...
    Jun 7, 2017 · ... density (g cm−3) for chert and shale beds assumed to be 2.46g cm−3 ... Monsoon as a cause of radiolarite in the Tethyan realm. Comp ...
  9. [9]
    Radiolarite - an overview | ScienceDirect Topics
    Radiolarites are defined as sedimentary rock deposits primarily composed of radiolarian siliceous remains, which are typically associated with highly productive ...Missing: iron | Show results with:iron
  10. [10]
    Radiolarite: Mineral information, data and localities.
    A siliceous-rock composed predominantly of radiolaria and with porosity greater than 50%. Wikipedia describes it as follows: "Radiolarite is a siliceous, ...About Radiolarite · MineralogyMissing: composition | Show results with:composition
  11. [11]
    The Horizontal Distribution of Siliceous Planktonic Radiolarian ...
    Radiolarian are key players in biogeochemical processes such as transformation of silica and carbon. Their composition and distribution characteristics in ...
  12. [12]
    New evaluation of species‐specific biogenic silica flux of ... - ASLO
    Sep 7, 2021 · We studied time-series fluxes of radiolarian particles collected by two sediment traps deployed at the eastern (Sta. NAP12t) and western (Sta.
  13. [13]
    Radiolarian skeletons: size, weight, sinking speed, and residence ...
    The sinking speeds of skeletal remains of 55 radiolarian species measured in 3, 10, and 20°C seawater range from 13 to 416 m day −3.Missing: transit seafloor percentage
  14. [14]
    [PDF] Biosiliceous Sedimentation, Radiolarite Periods and Silica Budget ...
    Most siliceous deposits are related to areas of high planktonic proouctivity. the equatorial zone being pliTticularly important through geologicat time.
  15. [15]
    Silicon Isotope Signatures of Radiolaria Reveal Taxon-Specific ...
    Along the Peruvian coast, strong annual upwelling delivers high nutrient subsurface waters to the surface, inducing intense surface productivity (Messié and ...Missing: rich m²/
  16. [16]
    Monsoon as a cause of radiolarite in the Tethyan realm
    The primary aim of this study is to discuss the importance of monsoon-driven upwelling for radiolarite deposition in the Mesozoic. ... episodes of increasing ...
  17. [17]
    [PDF] 8. Site 73 - Deep Sea Drilling Project
    The radiolarian-nannofossil oozes are mainly composed of calcareous nanno- plankton (45 to 60 per cent) with Radiolaria (30 to 50 per cent), foraminifera (0 to ...
  18. [18]
    Chapter 13 Opal-A to Opal-Ct Transformation: A Kinetic Study
    Aug 7, 2025 · Kinetic experiments on the opal-A to opal-CT transformation were conducted at 50°, 75°, 100°, 125°, and 150°C, in 0.03 M MgCl2 and 0.03 M ...Missing: radiolarite | Show results with:radiolarite
  19. [19]
    Porosity Reduction During Diagenesis of Diatomaceous Rocks
    Mar 2, 2017 · With decreasing porosity in group 2 samples, total content of silica minerals increases; therefore, as porosity decreases, the amount of clay ...Missing: radiolarites | Show results with:radiolarites
  20. [20]
    Temperature–time relationships and their implications for thermal ...
    The opal-A to opal-CT transition leads to abrupt changes in the sediment petrophysics which are used to identify the diagenetic interval at the study sites.Missing: radiolarite | Show results with:radiolarite
  21. [21]
    (PDF) Fossilization of radiolarian skeletons - ResearchGate
    Aug 5, 2025 · Transformation of opal A into opal CT and quartz is under control of temperature and time. ... transformed into globular opal CT during diagenesis ...
  22. [22]
    [PDF] Oxygen isotope analysis of Mesozoic radiolarites using SIMS
    Nov 12, 2020 · Here we used SIMS for the Mesozoic radiolarian δ18O to examine their paleoceanographic and diagenetic imprints. 2. Materials. We collected 55 ...
  23. [23]
    [PDF] Si isotope ratio of radiolaria across Triassic–Jurassic transition in a ...
    The study found δ30Si of radiolaria between -0.6±0.5‰ and 2.6±0.3‰, with negative excursions (SIE 1 and 2) during the end-Triassic turnover.
  24. [24]
    Compaction and dewatering processes of the oceanic sediments in ...
    Sep 15, 2001 · On the Barbados margin, a layer of radiolarian clay exists, providing a narrow zone of mechanical weakness and anomalously high dewatering in ...Missing: radiolarite | Show results with:radiolarite
  25. [25]
    Radiolarite - ALEX STREKEISEN
    Radiolarite is a siliceous fine-grained chert-like rock that is composed predominantly of the microscopic remains of radiolarians.Missing: geology | Show results with:geology
  26. [26]
    Bedding rhythms in Triassic basins of the Southern Alps
    Oct 25, 2016 · Middle Triassic intraplatform basinal calcareous turbidites with precise radiometric age control yielded an average sedimentation rate of 13.5 m ...Missing: 7-15.5 | Show results with:7-15.5<|separator|>
  27. [27]
    Geology and Geomorphology of Barbados: A Companion Text to ...
    Aug 6, 2025 · ... Barbados. A sedimentation rate of 27 m/m.y. for the Late Eocene is calculated. The spread of events through time does not suggest any ...
  28. [28]
    The chemical composition of subducting sediment and its ...
    Apr 15, 1998 · The sedimentation rate is inversely proportional to the concentration of hydrogenous phases and to the length of exposure of fish teeth to ...
  29. [29]
    Santonian-early Maastrichtian radiolarian biostratigraphy of the ...
    Oct 1, 2024 · We present one of the most diverse radiolarian assemblages recovered from Santonian-lower Maastrichtian strata in Arctic regions and the Interiors of North ...
  30. [30]
    Middle Triassic radiolarite pebbles in the Middle Jurassic Hallstatt ...
    Aug 6, 2025 · Middle Triassic radiolarites are a common sedimentary feature in the distal passive margin setting of the Neotethys. In contrast, Upper Triassic ...
  31. [31]
    A snapshot of the Late Jurassic Western Tethys seafloor ...
    Jul 24, 2013 · Deposition of these sediments in the Western Tethys occurred in relatively deep basins below the local calcite compensation depth (CCD).
  32. [32]
    [PDF] Deep Sea Drilling Project Initial Reports Volume 44
    During Late Jurassic time, two types of sediments were deposited: radiolarites, below the CCD, followed by limestones, perhaps following a depression of the CCD ...
  33. [33]
    The Innovative Structural and Physical Properties of Radiolaria
    Radiolarite is a type of chert-like sedimentary rock with a high silica content, formed by complex geological processes that offer a glimpse into ancient ...
  34. [34]
    Shallow-Water Origin of Radiolarites in Southern Turkey
    How- ever, most, if not all, radiolarite deposits in. Turkey are shallow-water sediments. This can be proved as follows: i. Red chert beds, with or without ...
  35. [35]
    Jurassic radiolarites in a Tethyan continental margin (Subbetic, southern Spain): palaeobathymetric and biostratigraphic considerations
    ### Summary of Jurassic Radiolarites in a Tethyan Continental Margin (Subbetic, Southern Spain)
  36. [36]
    (PDF) Mesozoic radiolarites - accumulation as a function of sea ...
    Aug 7, 2025 · Radiolarites, commonly comprising chert-shale couplets, feature prominently in the Mesozoic stratigraphy of the Neotethyan realm.
  37. [37]
    [PDF] 36. data report: formation microscanner imagery of lower cretaceous ...
    ... Milankovitch ... Callovian banding is caused by alternations of claystone and granular radiolarite, whereas the Oxfordian banding is due to clayey radiolarite ...
  38. [38]
    [PDF] 1. cenozoic and mesozoic sediments from the pigafetta basin, leg 129
    Detrital and eolian terrigenous input began to be significant during the Late Cretaceous and early Cenozoic. The surficial, condensed red clay (stage 6) ...
  39. [39]
    [PDF] Middle to late Jurassic carbonate-biosiliceous sediMentation and ...
    The occurrence of rhythmically alternating chert-shale couplets is typical of the ribbon radiolarites studied. ... The evolution of the Meliata-Hallstatt Ocean ...
  40. [40]
    [PDF] 30. milankovitch cycles in upper jurassic and lower cretaceous ...
    banding below a major clay-rich zone; (2) 352 mbsf, very siliceous ... chert-rich radiolarite to clay-rich radiolarite (Fig. 11), and correlates to ...
  41. [41]
    Petrography of Late Cambrian to Middle Ordovician radiolarian chert ...
    Feb 7, 2020 · Upper Cambrian to Middle Ordovician radiolarian chert successions from Kazakhstan were studied to clarify the history of the emergence of ...Missing: radiolarite | Show results with:radiolarite
  42. [42]
    Late Cambrian Radiolaria from Hunan, China
    May 20, 2016 · Confirming earlier, questionable reports of Cambrian Radiolaria, these fossils place the first appearance of the group somewhat before its ...<|control11|><|separator|>
  43. [43]
    Middle Ordovician (Darriwilian) radiolarians from the Crawford ...
    Apr 29, 2020 · A diverse assemblage of moderately well-preserved radiolarians occurs in the Ordovician cherts of the Crawford Group in the Southern Uplands ...Missing: radiolarite | Show results with:radiolarite
  44. [44]
    [PDF] Devonian, in 1C.H. Shultz ed., The Geology of Pennsylvania
    Available data indicate that during the Devo nian, the Appalachian basin lay in the southern hemi sphere near the equator, as shown in Figure 7-20. Figure 7-17.Missing: radiolarite | Show results with:radiolarite
  45. [45]
    New Radiolarian Species from the Lower Carboniferous of the ...
    Aug 25, 2023 · The stratotype of the Usolka Section is located in the South Urals in the Gafuriysky District of the Republic of Bashkortostan (Fig. 1). The ...Missing: radiolarite | Show results with:radiolarite
  46. [46]
    [PDF] Historical insights on nearly 130 years of research on Paleozoic ...
    Sep 29, 2017 · The first Paleozoic radiolarian genera were defined by Hinde (1890) on the basis of material from the Southern Uplands (Scotland, United ...Missing: radiolarite | Show results with:radiolarite
  47. [47]
    Early Paleozoic radiolarian plankton diversity and the Great ...
    Based on a new and exhaustive sample-based dataset of middle Cambrian to Silurian radiolarian occurrences we investigate the diversity patterns of all ...Missing: radiolarite | Show results with:radiolarite
  48. [48]
    Possible oldest radiolarians from deep-water chert and phylogenetic ...
    Aug 15, 2021 · They were considered to occur in the early Cambrian, which could be part of the Cambrian explosion and biomineralization event of the latest ...Missing: radiolarite | Show results with:radiolarite
  49. [49]
    Stratigraphic evolution of the Triassic–Jurassic succession in the ...
    May 18, 2009 · The Triassic–Lower Jurassic succession of the Southern Alps is characterized by rapid thickness changes, from an average of about 5000 m ...
  50. [50]
    Geology and radiolarian fossils of the Upper Cretaceous Hanazono ...
    Aug 7, 2025 · Radiolarian fossils were obtained from chert, felsic tuff, shale and tuffaceous shale of the Hanazono, Yukawa and Miyama Formations, and 4 ...Missing: radiolarite | Show results with:radiolarite
  51. [51]
    An example from the Franciscan Complex of Northern California
    The Yolla Bolly terrane of the Franciscan Complex consists of rare metabasalt overlain by bedded radiolarian chert which in turn is overlain by ...
  52. [52]
    Late Anisian platform drowning and radiolarite deposition as a ...
    Jul 1, 2012 · The radiolarite event occurred shortly after the main subsidence pulse and the final break-up of the Neotethys ocean, and was concomitant with ...
  53. [53]
    Upper Jurassic radiolarian assemblages and chert geochemistry of ...
    Well-preserved Upper Jurassic (Tithonian) radiolarian assemblages have been recovered from bedded cherts in the Shiquanhe ophiolite.
  54. [54]
    The Toarcian radiolarian event in bedded cherts from southwestern ...
    A drastic faunal turnover of radiolarians in the early Toarcian, termed the Toarcian Radiolarian Event (TRE), recognized in bedded chert sequences of ...Missing: radiolarite | Show results with:radiolarite
  55. [55]
    Inventory of Cenozoic radiolarian species (Class Polycystinea)
    Feb 3, 2022 · - Cenozoic radiolarians from the Barbados Ridge, Lesser Antilles subduction complex, Deep Sea Drilling Project Leg 78A, in BIJU- DUVAL B ...Missing: radiolarite | Show results with:radiolarite
  56. [56]
    [PDF] Radiolarians from the cyclic Messinian diatomites of Falconara ...
    The main goal of this paper is to examine the polycystine radiolarian fauna in the biosiliceous deposits in the Tripoli Formation as it outcrops at Falconara, ...Missing: radiolarite | Show results with:radiolarite<|separator|>
  57. [57]
    [PDF] new species of neogene radiolarians from the southern ocean - JM
    Range chart of the twenty-five new species described herein. Antarctic radiolarian zonation follows Abelmann (1992) and Lazarus (1992). Numerical age of zonal ...Missing: radiolarite | Show results with:radiolarite
  58. [58]
    New record of siliceous, marine, later Eocene from Kalbarri, Western ...
    May 20, 2025 · New record of siliceous, marine, later Eocene from Kalbarri, Western Australia ... Radiolaria of the Windalia. Radiolarite (type section), ...
  59. [59]
    Monsoon as a cause of radiolarite in the Tethyan realm
    Higher sedimentation rates of both radiolarians and diatoms are interpreted as resulting from intervals of higher paleoproductivity related to periods of ...
  60. [60]
    (PDF) A new low-latitude late Paleocene-early Eocene radiolarian ...
    Aug 6, 2025 · A new late Paleocene to early Eocene low-latitude radiolarian zonation suited for the correlation of accreted terranes is established by using ...
  61. [61]
    From Neo-Tethyan convergence to India-Asia collision: radiolarian ...
    Aug 6, 2025 · Radiolarian chert generally accumulates below the CCD (Boggs, 2009; Li et al., 2023) and could indicate the Early Cretaceous deposition near the ...Missing: remnants | Show results with:remnants
  62. [62]
    The Southern Ocean Radiolarian (SO-RAD) dataset
    Nov 25, 2021 · The Southern Ocean Radiolarian (SO-RAD) dataset includes census counts for 238 radiolarian taxa from 228 surface sediment samples located in the Atlantic, ...
  63. [63]
    Review of radiolarian microfossils as a tool for reconstructing sea ...
    May 19, 2025 · In this review we re-evaluated the potential of radiolarian species as palaeoceanographic proxies in the Northwest Pacific Ocean relying on 33 new samples ...Missing: radiolarite | Show results with:radiolarite
  64. [64]
    Radiolarians decreased silicification as an evolutionary response to ...
    Here, radiolarian silicification decreased insignificantly (r = 0.58, P = 0.1), from ≈0.13 at 35 Ma to 0.11 today. Trends in shell size in both time series are ...
  65. [65]
    Silica, diatoms, and Cenozoic radiolarian evolution | Geology
    Jun 2, 2017 · Such trends include decrease in test weight, as well as structural changes such as increased pore size, decreased bar width, reduction or loss ...Missing: declining radiolarite
  66. [66]
    Radiolarian Biostratigraphy and Evolution in the Upper Cretaceous
    In parallel, a radiolarian-based zonal scheme emerging from the Tethyan regions of Eurasia has provided a refined subdivision of the Upper Cretaceous strata, ...
  67. [67]
    Radiolarian-Based zonal scheme of the cretaceous (Albian ...
    Aug 7, 2025 · A scheme of radiolarian zonal subdivision is proposed for the upper Albian–Santonian of the Tethyan regions of Eurasia.
  68. [68]
    Progress in the taxonomy of Late Cretaceous high-latitude radiolarians
    May 3, 2024 · The specimens were recovered from the Santonian–middle Campanian Smoking Hills Formation and the middle Campanian–Maastrichtian Mason River ...
  69. [69]
    [PDF] Radiolarian palaeoecology and radiolarites
    Jun 25, 2018 · Radiolarian productivity pulses and related radiolarite deposition are phenomena difficult to understand from an.
  70. [70]
    Radiolarian and sedimentologic paleoproductivity proxies in late ...
    Prior research has established that late Pleistocene glacial intervals in this upwelling system generally had higher productivity than interglacials. The ...
  71. [71]
    Early Triassic (Induan) Radiolaria and carbon-isotope ratios of a ...
    Aug 6, 2025 · This study examines a Triassic deep-sea sequence consisting of rhythmically bedded radiolarian cherts and shales and its implications for ...
  72. [72]
    Implications for the evolution of the Neo-Tethys Ocean - ScienceDirect
    Oct 3, 2025 · This study reports the discovery of well-preserved Late Cretaceous radiolarians from the Duobeng Formation and establishes a radiolarian ...Missing: radiolarite | Show results with:radiolarite
  73. [73]
    Origin and implications of early diagenetic quartz in the ...
    Dissolution of siliceous radiolarian tests during early diagenesis is identified as the main source of silica (opal A) required for quartz precipitation ...
  74. [74]
    Integrated Radiolaria, benthic foraminifera and conodont ...
    Dec 2, 2018 · 4 DATING OF PERMIAN SEQUENCES. Permian sequences within the Mersin Mélange have been dated by using radiolarians, benthonic foraminifera and ...
  75. [75]
    GemeindeBergBau: Extensive radiolarite mining at the Vienna ...
    First excavations took place already in the 19th century. Although the use of the local radiolarite was implied, the actual mining site could never be verified.
  76. [76]
    [PDF] LITHIC RESOURCES IN THE EARLY PREHISTORY OF THE ALPS*
    Rocks, which are ubiquitous in archaeological sites as chipped or polished tools, were important factors in the prehistoric Alpine economic system.
  77. [77]
    La Pietra and other radiolarite quarry-workshops in Tuscany
    Sep 15, 2016 · In central-southern Tuscany radiolarite has been used as a lithic raw material throughout prehistory. During the Copper Age it was selected ...Missing: Alps | Show results with:Alps
  78. [78]
    Black chert and radiolarite: knappable lithic raw materials in the ...
    Jun 9, 2021 · Chert and radiolarite are raw materials that were used by the prehistoric groups that occupied this territory for thousands of years.
  79. [79]
    Multimodal elemental analysis: A unique tool for the provenance of radiolarite artefacts
    ### Summary of Prehistoric Uses of Radiolarite for Stone Tools, Knapping, and Examples from Europe/Asia