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Silex
Silex
Silex
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Silex is any of various forms of ground stone. In modern contexts the word refers to a finely ground, nearly pure form of silica or silicate.

In the late 16th century, it meant powdered or ground up "flints" (i.e. stones, generally meaning the class of "hard rocks").[1]

It was later used in 1787 when describing experiments in a published paper by Antoine Lavoisier where such earths are mentioned as the source of his isolation of the element silicon. Silex is now most commonly used to describe finely ground silicates used as pigments in paint.

Archaic and foreign uses

[edit]
  • The word silex was previously used to refer to flint and chert and sometimes other hard rocks.
  • In Latin silex originally referred to any hard rock, although now it often refers specifically to flint.[2]
  • In many Romance languages, silex or a similar word is used to refer to flint. Although the modern English word silex has the same etymology, its current meaning has changed. These are false friends.
  • FK Sileks is a football club based in Kratovo, North Macedonia whose name literally means 'flint'.

References

[edit]
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Silex

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from Grokipedia
Silex is a hard, siliceous rock primarily composed of microcrystalline quartz (SiO₂), often synonymous with flint or chert, valued historically for tool-making and in modern applications as a ground filler material. The term derives from the Latin silex, meaning "hard stone" or "flint," with its first recorded English use around 1592. In geological contexts, silex refers to cryptocrystalline forms of silica that form as nodules or layers in sedimentary rocks, typically through the accumulation and recrystallization of biogenic silica from marine organisms such as sponges, diatoms, and radiolarians during the Late Cretaceous period (approximately 100–66 million years ago). These formations exhibit a conchoidal fracture, enabling sharp edges, and often contain fossil inclusions like echinoid fragments or sponge spicules. Historically, silex has been a key raw material for human technology since the era, over 1.5 million years ago, used to craft knives, arrowheads, and axes due to its durability and ease of . Neolithic mining sites, such as in , demonstrate large-scale extraction for these purposes. It also served in fire-starting mechanisms, like flintlocks in firearms, until the , and in , as seen in paved with silex blocks. In contemporary uses, finely ground silex—often as powdered tripoli or high-purity silica—functions as an inert filler in paints, wood finishes, dental materials, and , leveraging its and abrasiveness. Geologically, it occurs worldwide in and deposits, with notable sources in Europe's cliffs and American sedimentary basins.

Definition and Etymology

Definition

Silex refers to various forms of siliceous materials, primarily a composed of (SiO₂), often synonymous with flint or chert in geological and historical contexts. In modern industrial applications, silex denotes a finely ground, nearly pure form of silica, typically in form with particle sizes ranging from 1 to 100 microns and purity levels exceeding 99% SiO₂. Unlike raw silica sand, which consists of coarser grains often containing impurities, industrial silex undergoes refinement for uniformity in specialized uses. Common forms include amorphous varieties, such as powdered tripoli, and ground crystalline silica.

Etymology

The term "silex" originates from the Latin word sīlex (genitive silicis), denoting a hard stone, flint, or pebble. This usage appears in texts, including Pliny the Elder's Naturalis Historia (1st century AD), where silex refers to various hard stones employed in and tools, such as river-found flint noted for its damp quality. In the evolution of , the Latin sīlex influenced terms for flint and similar hard stones. In French, it directly yielded silex, retaining the sense of flint. Italian developed selce from sīlex, commonly used for flint. Spanish uses sílex for flint, alongside pedernal derived from other influences, with sílex common in scientific contexts. The word entered scientific in the , particularly in chemistry, where silex designated siliceous or vitrifiable earths—proto-references to silica compounds. This adoption is evident in the Méthode de nomenclature chimique by Guyton de Morveau, Lavoisier, Berthollet, and Fourcroy, which listed "silex" among simple substances to standardize chemical terms.

Properties

Physical Properties

Silex, as a quartz-based material primarily composed of (SiO₂), possesses a of approximately 2.65 g/cm³, which contributes to its effectiveness as a dense grinding medium. This density is characteristic of high-purity forms used in industrial applications. The material exhibits a of 7 on the , owing to its dominant content, enabling it to withstand conditions without significant wear. In processed grades, silex is ground to controlled distributions, typically yielding 325 (44 microns) or finer particles to suit precise mixing requirements. Silex appears as a to colorless in its finely divided form and is non-porous when pure, facilitating clean and efficient . Thermally, it demonstrates stability below 573°C with a high around 1710°C and low ; however, it undergoes an alpha-to-beta at approximately 573°C, resulting in a volume change that can cause deformation or cracking under certain conditions.

Chemical Properties

Silex is predominantly composed of (SiO₂), with content ranging from 96.9% to 99.5%, accompanied by trace impurities such as aluminum oxide (Al₂O₃) up to 0.34% and (Fe₂O₃) up to 0.29%. This composition reflects its derivation from high-purity natural sources. Under standard conditions, silex demonstrates chemical inertness and remains insoluble in , exhibiting a solubility of approximately 0.01 g/100 mL at 20°C. Its stability stems from the strong covalent bonds in the SiO₂ network structure. At elevated temperatures, silex becomes reactive, fusing with fluxes to form various compounds. It also reacts with strong bases, such as (NaOH), particularly under heating, to produce . The silica in silex behaves as a , reacting with strong bases but resistant to most acids except .

Sources and Production

Natural Sources

Silex, a form of silica (SiO₂), occurs primarily as nodules, layers, or beds within sedimentary rocks, especially limestones and chalks formed during the period through the accumulation and diagenetic recrystallization of biogenic silica from marine organisms such as sponges, diatoms, and radiolarians. These deposits exhibit high silica content, typically 98–99% SiO₂, with impurities including iron oxides and fragments. Unlike macrocrystalline from igneous or metamorphic sources, silex forms via replacement of in limestones under low-temperature conditions, concentrating silica in irregular concretions or tabular layers. Globally, prominent sources include chalk formations in , such as the black flint beds of and the Cliffs of Dover in , and similar deposits in northern and . In , notable occurrences are the Alibates Flint Quarries in (Upper ) and chert beds in the Midcontinent region. For finely divided forms used industrially, silex derives from tripoli deposits—microcrystalline silica resulting from the and leaching of chert, , or siliceous limestones—primarily in the United States, including the and Ozark Plateaus of (Mississippian ) and southern (silicified rocks). These tripoli sources yield material with particle sizes of 0.1–10 micrometers and purity exceeding 99% SiO₂. While silica resources overall are abundant worldwide, high-quality silex and tripoli deposits are more localized to specific sedimentary basins with suitable biogenic silica accumulation.

Production Methods

Production of silex, whether as raw rock for historical uses or ground powder for modern applications, begins with mining from sedimentary deposits using open-pit methods for surface exposures or underground techniques for deeper beds, as seen in Neolithic sites like or modern tripoli operations. In contemporary industrial production, particularly for powdered silex (tripoli), raw material is extracted via open-pit or underground mining in regions like , followed by initial drying to remove moisture. The ore is then crushed and pulverized using jaw crushers, hammer mills, or ball mills to achieve fine particle sizes, typically 10–325 (44–2000 micrometers) for fillers and abrasives. Grinding often employs silica-based media to avoid contamination, with energy consumption around 50–100 kWh per ton depending on target fineness. Classification follows via air flotation, screening, or hydrocyclones to separate size fractions, yielding uniform grades for applications like paints or dental materials. Final drying in rotary kilns reduces moisture to below 0.5%, and the powder is packaged to maintain purity, typically above 99% SiO₂ without chemical leaching. In the United States, tripoli production reached approximately 79,700 tons in , primarily from and other states, supporting uses as inert fillers and abrasives.

Applications

Industrial Applications

Silex, a high-purity form of silica, plays a central role in , accounting for about 70% of the raw material batch in soda-lime glass manufacturing, where it functions as the primary network former, , and clarifier to promote melting and gas removal for improved clarity. In specialty glass applications, such as optical fibers and continuous filament glass, silex with impurity levels below 10 ppm is essential to minimize light scattering and ensure superior . In ceramics and refractories, silex serves as a key additive in formulations and high-temperature bricks, contributing up to 30% of the body composition to enhance , reduce shrinkage, and improve overall mechanical strength and thermal stability. Silex is widely employed in filtration systems for , acting as an effective support and filtering medium to remove and particulates through mechanical straining and adsorption processes. As an abrasive material, is incorporated into media for surface cleaning and preparation in , as well as compounds for metallurgical applications, leveraging its to achieve precise finishes without excessive material removal. Global demand for silex in these industrial sectors is estimated at approximately 370 million tons annually, with a of around $12.2 billion based on 2023 figures.

Agricultural and Other Applications

In , silex, primarily in the form of soluble silicates such as blends with an NPK ratio of 0-0-12, serves as a bio-available silica supplement to enhance resilience. These supplements strengthen cell walls by depositing silica in epidermal tissues, improving structural and resistance to biotic stresses like pests and fungal pathogens, as well as abiotic factors such as and . For instance, foliar or soil applications of have been shown to significantly reduce rice blast incidence through induced defense mechanisms. Beyond agriculture, silex functions as a key precursor in electronics for producing high-purity silicon used in semiconductor wafers. Through carbothermic reduction of silica sand (SiO₂) at temperatures exceeding 1500°C, metallurgical-grade silicon is obtained and further purified via the Siemens process to achieve electronic-grade silicon with impurity levels below 1 ppb. This silicon is then grown into single-crystal ingots via the Czochralski method and sliced into wafers essential for integrated circuits and photovoltaic cells. In cosmetics and pharmaceuticals, precipitated or fumed silex acts as a multifunctional , serving as a thickener to improve product and an anti-caking agent to prevent clumping. In cosmetic formulations, silica microspheres provide a soft-focus effect and oil absorption, enhancing texture in foundations and at concentrations up to 15%. Similarly, in pharmaceuticals, it ensures free-flowing properties in tablet coatings and powdered drugs, with the U.S. FDA recognizing silica as GRAS for such uses. Environmentally, silex-based amendments, particularly silicate-rich materials, are applied to contaminated soils to immobilize through adsorption and . These amendments increase and provide negatively charged surfaces that bind cations like Cd²⁺, Pb²⁺, and Zn²⁺, reducing their to by 13-30% in amended soils. For example, silicon-rich derived from silica sources has demonstrated effective stabilization of multiple in cultivation, minimizing uptake into edible parts. Emerging applications of silex post-2020 include its integration into filaments and anodes, with ongoing advancements as of 2025. In additive manufacturing, silica-infused filaments, such as polycarbonate-silica composites, enhance mechanical strength and thermal stability for producing durable prototypes and ceramics. These filaments exhibit up to 20% improved tensile strength compared to pure , enabling high-resolution printing of silica-based scaffolds for biomedical uses. For , silica serves as a precursor or buffer in silicon anodes, where nanostructured SiO₂ coatings mitigate volume expansion during lithiation, achieving cycle life improvements of over 500 cycles at capacities exceeding 1000 mAh/g. Recent advancements, such as SiOₓ-based anodes with metal doping, have boosted initial Coulombic to 85%, addressing barriers for high-energy-density batteries.

History

Archaic and Early Uses

In the Paleolithic era, beginning around 2.6 million years ago, early humans knapped flint, known as silex in Latin, into sharp tools such as knives, scrapers, and projectile points, marking one of the earliest uses of this hard siliceous rock for practical purposes. These tools, produced through techniques like the Levallois method in later phases, enabled hunting, butchering, and woodworking, with evidence from sites across and showing flint's prevalence due to its conchoidal fracture that yielded keen edges. By the period, around 3000 BCE, flint extraction intensified for more specialized implements, as seen at in , , where miners dug over 400 shafts up to 15 meters deep to access high-quality nodules for crafting polished axes, adzes, and sickles used in and . Concurrently, ground flint or served as a key component in ancient ceramics; in from approximately 3000 BCE, it formed the siliceous body of , a glazed non-clay material molded into beads, amulets, and vessels, where crushed quartz particles (92-99% silica) were mixed with lime and before firing to create a durable, turquoise-hued surface. In the Roman era, ground silex contributed to hydraulic mortars like , a lime-based incorporating crushed stone aggregates, including flint in regions with local availability, to waterproof floors, walls, and cisterns for enhanced durability against moisture. During the medieval period, silex stones, valued for their hardness, were employed in rotary querns—hand-operated mills consisting of two circular stones—for grinding grains into , a practice evident in European archaeological finds where flint or upper stones rotated against lower bases to process cereals efficiently in households and small communities. As emerged in the 16th and 17th centuries, "earth of " denoted calcined flint or purified silica powder, integrated into making recipes to form the vitreous base; Italian alchemist and glassmaker Antonio Neri, in his 1612 treatise L'Arte Vetraria, described using such preparations with alkalis and metal oxides to produce clear cristallo , bridging empirical craft with proto-chemical experimentation.

Modern Developments

In the late , advancements in chemical marked a pivotal shift in understanding silex, or silica. In 1787, French chemist conducted experiments on silica, proposing it as an oxide of an unknown element and adopting the term "silex" from Latin to denote this "siliceous ," which laid the groundwork for recognizing silica's elemental composition. This insight culminated in 1824 when Swedish chemist isolated elemental by heating potassium fluorosilicate with potassium, confirming silica as and enabling further scientific exploration of silex's properties. Berzelius's work transitioned silex from a rudimentary material to a subject of systematic chemistry, influencing subsequent industrial applications. The 19th century saw the drive mechanized production of silex, particularly for the burgeoning glass industry. Innovations in steam-powered machinery facilitated large-scale grinding of flint and silex into fine abrasives, essential for polishing and cutting on an unprecedented scale, which supported the era's expansion in window, bottle, and optical manufacturing. This scale-up not only reduced manual labor but also improved uniformity in glass quality, aligning with broader mechanization trends that transformed silex from artisanal tool material to industrial staple. By the mid-20th century, demands for higher purity propelled innovations in silex processing for emerging . Starting in the , acid-leaching techniques were developed to purify silica sands and , removing impurities like iron and aluminum to produce high-grade silex suitable for production, coinciding with the transistor's and the need for ultra-pure insulators. These methods enhanced silex's role in , enabling reliable layers in integrated circuits. Post-2000 developments emphasized and advanced applications of silex derivatives. Nano-silex, or silica nanoparticles, gained prominence in for and , with mesoporous structures allowing controlled release and , as demonstrated in theranostic systems for cancer and treatment since the early 2000s. Concurrently, environmental regulations addressed health risks from silex dust; the U.S. (OSHA) established its initial for respirable crystalline silica in 1971 at 100 micrograms per cubic meter, prompting safer handling practices in and . Sustainable sourcing initiatives, including recycled and low-impact , have since reduced ecological footprints in silex production. Global trade in silex has shifted toward high-tech sectors, notably , where purified silica is vital for wafers in solar panels. Since 2010, the market—derived from silex—has expanded at a exceeding 14%, driven by solar capacity additions that reached over 1 terawatt globally by 2022, reflecting a broader transition to technologies.

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