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Selenium dioxide

Selenium dioxide (SeO₂) is an inorganic composed of one atom bonded to two oxygen atoms in the +4 , existing as the anhydride of selenious . It appears as a white or creamy-white, lustrous crystalline powder or volatile crystals with a pungent, sour , and is highly soluble in , where it reacts to form selenious (H₂SeO₃). Physically, selenium dioxide has a of 340 °C, sublimes at approximately 315–317 °C, and possesses a of 3.95 g/cm³ at 25 °C; it is also soluble in alcohols such as and , as well as in acetone and acetic , but insoluble in nonpolar solvents like . Chemically, it functions as a strong , capable of introducing carbonyl groups at activated carbons in organic molecules and facilitating allylic reactions. It is produced industrially by burning elemental in oxygen or air, or by oxidizing with , often as a in processes like refining and purification. Selenium dioxide finds applications in as a reagent for the oxidation of allylic and benzylic positions in alkenes and alkynes, in the manufacture of decolorizers and colorants to produce ruby-red tones, and as a in photographic processes. It is also used in production, and in for reactions with o-diamines. Environmentally, it can volatilize from heated sources as "selenium fumes" (containing 20–80% SeO₂) and bind to iron and aluminum oxides in soils, reducing its , though it contributes to contamination in and from industrial emissions. Despite its utility, selenium dioxide is acutely toxic, with an oral LD50 of approximately 68 mg/kg in rats and inhalation LC50 values as low as 0.15–0.6 mg/L for 0.5–4 hours, causing severe respiratory irritation, , skin burns, and systemic effects like garlicky breath, , and liver damage upon exposure. Chronic occupational exposure at levels of 0.1–0.78 mg/m³ has been associated with , , , and potential selenosis, necessitating strict handling precautions; interestingly, at low pharmacological doses (e.g., 0.1–6 mg/kg in food), certain selenium compounds including derivatives show anticarcinogenic properties in animal studies, though high doses may pose carcinogenic risks.

Structure

Crystal structure

Selenium dioxide (SeO₂) in its solid state forms a one-dimensional polymeric structure composed of infinite chains, in which selenium atoms are bridged by oxygen atoms via asymmetric Se-O-Se linkages, with each selenium atom coordinated to two terminal oxygen atoms in a nearly tetrahedral arrangement. This chain-like arises from the tendency of SeO₂ to oligomerize through bridging oxygens, contrasting with the discrete molecular units observed in related compounds like SO₂. The crystal system is tetragonal, belonging to the space group P4₂/mbc (No. 135), with lattice parameters a = b = 8.36 Å and c = 5.06 Å (Z = 8). X-ray diffraction studies on single crystals confirmed this chain structure, revealing bond lengths of approximately 1.62 Å for terminal Se–O and 1.79 Å for bridging Se–O, indicative of partial double-bond character in the terminal linkages. This polymeric arrangement bears resemblance to the extended network in (SiO₂), but features weaker Se-O bonding due to the larger size and lower of , which contributes to the compound's and ease of . In the gas phase, however, SeO₂ depolymerizes to monomeric molecules with a bent similar to SO₂.

Molecular geometry

Selenium dioxide in the gas phase exists as isolated monomeric molecules with a and C_{2v} symmetry. This structure arises from the central atom bonded to two oxygen atoms, with the Se=O bonds exhibiting double-bond character. According to valence shell electron pair repulsion (, the SeO_2 is classified as AX_2E_1, where A is the central atom (Se), X represents bonding pairs to oxygen, and E denotes a on . The electron domain geometry is trigonal planar due to three electron pairs around (sp^2 hybridization), but the is bent as the occupies one position, repelling the bonds and reducing the O-Se-O bond angle from the ideal 120° to approximately 114°. The equilibrium for each Se=O is 1.608 Å. The asymmetry of this bent structure results in a significant of 2.62 D, directed from the atom toward the midpoint between the oxygen atoms. Spectroscopic studies confirm this : provides the rotational constants consistent with C_{2v} symmetry and the measured structural parameters, while (IR) and Raman spectra in the gas phase reveal characteristic vibrational modes, including the symmetric stretch (ν_1 at ~921 cm^{-1}, Raman active), bending (ν_2 at ~370 cm^{-1}, IR and Raman active), and asymmetric stretch (ν_3 at ~968 cm^{-1}, IR active). This polar bent geometry enhances the molecule's reactivity as a mild oxidant in , facilitating selective allylic oxidations.

Properties

Physical properties

Selenium dioxide is a white to off-white crystalline solid, often appearing as lustrous, hygroscopic crystals or powder, with a of 110.96 g/mol. It has a of 3.95 g/cm³ at 25 °C. The exhibits a pungent, sour reminiscent of rotten radishes, particularly noticeable in its yellowish-green vapor when heated. Under standard conditions, selenium dioxide does not have a sharply defined ; it at approximately 315 °C at 1 and melts at 340 °C under (e.g., in a sealed tube). This behavior is influenced by its polymeric chain structure in the solid state, which contributes to the relatively high sublimation temperature. Selenium dioxide is soluble in , with a of about 39.5 g/100 mL at 25 °C, where it reacts to form (H₂SeO₃). It is also soluble in (6.7 g/100 mL at 15 °C) and acetone, but insoluble in non-polar solvents such as hydrocarbons. Thermodynamic data for selenium dioxide include a standard enthalpy of formation (ΔH_f°) of -234.0 kJ/mol and a standard of formation (ΔG_f°) of -186.9 kJ/mol at 298.15 for the solid phase.

Chemical properties

Selenium dioxide (SeO₂) exhibits amphoteric behavior, functioning as the anhydride of . It readily reacts with water to form via the hydration reaction: \ce{SeO2 + H2O -> H2SeO3} This process is exothermic, with a standard enthalpy of reaction (Δ_r H°) of approximately -13.5 kJ/mol. In SeO₂, selenium adopts the +4 oxidation state, enabling both oxidative and reductive transformations. It serves as a strong oxidizing agent and can be reduced to elemental selenium (Se(0)) or further oxidized to the +6 state as in selenium trioxide (SeO₃). The standard reduction potential for the Se(IV)/Se(0) couple, H₂SeO₃ + 4H⁺ + 4e⁻ ⇌ Se + 3H₂O, is 0.742 ± 0.002 V, underscoring its redox activity in aqueous acidic media. For instance, SeO₂ oxidizes iodide ions to iodine: \ce{SeO2 + 4I- + 6H+ -> Se + 2I2 + 3H2O} This reaction proceeds through the intermediate selenous acid formed in situ. SeO₂ demonstrates thermal instability at elevated temperatures, decomposing above 800°C via disproportionation: \ce{2SeO2 -> Se + SeO3} Under normal conditions, it sublimes at 315°C without significant decomposition, but heating leads to emission of toxic selenium vapors. The compound is highly hygroscopic, absorbing moisture from air to decompose into selenous acid, rendering it corrosive in humid environments. It remains stable and inert in dry air but readily reacts with reducing agents, such as hydrogen or organic reductants, to yield lower selenium oxidation states. In , SeO₂ acts as a selective oxidant, as exemplified by its role in the of allylic methylene groups to alcohols or carbonyls.

Synthesis and production

Laboratory preparation

A standard laboratory method involves the oxidation of elemental powder with concentrated . The reaction proceeds as follows: $3\mathrm{Se} + 4\mathrm{HNO_3} \rightarrow 3\mathrm{SeO_2} + 4\mathrm{NO} + 2\mathrm{H_2O} To perform this synthesis, powder is added gradually in small portions to an excess of concentrated while stirring, preventing excessive foaming from the evolved gas. The mixture is then gently heated to evaporate the solution to dryness, yielding crude dioxide as a residue. This approach ensures complete oxidation under controlled conditions suitable for small-scale . Another route employs direct aerial oxidation of elemental at elevated temperatures. follows the equation: \mathrm{Se} + \mathrm{O_2} \rightarrow \mathrm{SeO_2} Selenium is heated in a stream of air or oxygen to 500–600 °C in a suitable furnace or tube, where the dioxide sublimes as it forms and can be collected in a cooler section. This method requires careful temperature control to achieve efficient conversion without side reactions. Selenium dioxide can also be obtained by dehydration of selenous acid (H₂SeO₃). Upon heating the acid to approximately 180 °C, water is removed according to: \mathrm{H_2SeO_3} \rightarrow \mathrm{SeO_2} + \mathrm{H_2O} The selenous acid, typically prepared by dissolving selenium dioxide in water, is evaporated and heated in an open vessel or crucible until dehydration is complete, producing the anhydrous oxide. An alternative oxidation uses hydrogen peroxide with elemental selenium: \mathrm{Se} + 2\mathrm{H_2O_2} \rightarrow \mathrm{SeO_2} + 2\mathrm{H_2O} Selenium is reacted with excess hydrogen peroxide solution, often under mild heating, leading to the formation of selenium dioxide, which can then be isolated by evaporation. This method is milder than nitric acid oxidation and avoids nitrogen oxide byproducts. Regardless of the synthesis route, purification of the crude product is essential and commonly achieved by . The material is heated to around 315 °C in a sublimation apparatus, where pure selenium dioxide sublimes and deposits as white needles, effectively separating it from impurities such as unreacted or residual acids. This step yields high-purity selenium dioxide suitable for applications.

Industrial production

Selenium dioxide is primarily produced on an industrial scale by the controlled oxidation of metal in air or oxygen, following the reaction Se + O₂ → SeO₂, which occurs at elevated temperatures to ensure complete conversion and minimize side products. This is often integrated into facilities recovering from refining operations, where elemental is first isolated before oxidation to the dioxide form. Catalysts may be employed to enhance efficiency and yield in large-scale setups. A significant portion of selenium dioxide originates as an intermediate in the recovery of from slimes generated during electrolytic . These slimes, containing 5–25% , are mixed with and roasted at 500–600 °C, volatilizing as SeO₂ for collection. This method accounts for over 90% of global supply, making selenium dioxide closely tied to the industry. Additionally, SeO₂ can be obtained as a from plants processing selenium-impure feedstocks, such as pyrites or spent catalysts, where oxidation during captures in the gas stream. Global production of refined , primarily derived via selenium dioxide as an intermediate, was estimated at 3,700 metric tons ( content) in 2024, with as the leading producer contributing nearly 50% of refined selenium equivalents (USGS, 2025). The dioxide is purified via under reduced pressure or aqueous washing to achieve commercial grades exceeding 99% purity, suitable for downstream applications. Economic aspects include its status as a , which keeps costs low relative to , though energy inputs for and purification represent key operational considerations.

Occurrence

Natural minerals

Selenium dioxide occurs naturally as the rare mineral downeyite (SeO₂), the only known oxide mineral of . Downeyite was first verified in 1977 from acicular crystals formed by the of gases escaping through vents on burning culm banks in the region of , . Downeyite exhibits acicular or prismatic crystal habits and appears colorless to white, though inclusions of amorphous or can impart red or yellow hues, respectively. The mineral is highly hygroscopic, readily absorbing atmospheric moisture, and has a calculated of 4.146 g/cm³. With fewer than 10 confirmed localities worldwide, downeyite is extremely rare and typically occurs as delicate efflorescences. Additional occurrences include sublimed deposits from volcanic fumaroles at in , , and from processes in burning seams. Downeyite forms via low-temperature oxidation of elemental in arid, oxidizing environments, such as the volatile emissions during selenium-rich or volcanic activity. It is associated with native , rosickýite, and mascagnite in deposits from and volcanic activity.

Environmental sources

Selenium dioxide enters the atmosphere primarily through natural and emissions that lead to its formation via oxidation of elemental or other reduced forms. Volcanic gases release selenium compounds, which oxidize in the air to SeO2, contributing an estimated 0.4 to 1.2 gigagrams of selenium annually on a global scale. combustion, a major anthropogenic source, also emits selenium that converts to SeO2 in the atmosphere, with total global atmospheric selenium emissions ranging from 29 to 36 gigagrams per year, approximately doubling prior estimates. These fluxes highlight SeO2's role in atmospheric transport before deposition. In soils and water bodies, SeO2 occurs at trace levels through leaching from seleniferous rocks, particularly in oxidized environments where selenium mobilizes as soluble Se(IV) species. In the western United States, such as basins in and , weathering of marine shales releases selenium into soils and , forming trace amounts of SeO2 equivalents in aerated conditions. exacerbates this , transporting selenium into agricultural drainage waters at concentrations typically below 1 part per million. Within the biogeochemical , SeO2 serves as an intermediate in the oxidation pathway from selenium (Se(0)) to selenate (Se(VI)), facilitating its mobility across environmental compartments. This process involves microbial and abiotic oxidation in soils and waters, where Se(IV) as selenious acid (derived from SeO2 ) undergoes further . The underscores SeO2's transient presence in oxygenated settings before conversion to more stable forms. Detection of environmental SeO2 relies on spectroscopic techniques, such as (ICP-MS), applied to rainwater and sediments. Concentrations in these media are generally low, often less than 1 ppm for total , with SeO2 specifically identified through speciation analysis in oxidized samples. Historical volcanic activity has left legacies of selenium enrichment in soils, particularly from ancient eruptions that deposited volatile selenium compounds, oxidizing to SeO2 and contributing to seleniferous profiles in regions like the western U.S. These deposits influence long-term environmental cycling, occasionally elevating local selenium levels to thresholds associated with ecosystem toxicity.

Applications

Organic synthesis

Selenium dioxide serves as a key in , particularly through the , which selectively oxidizes allylic methylene groups to allylic alcohols while preserving the . This reaction is especially valuable for functionalizing alkenes in complex molecules, as demonstrated by the conversion of to 2-cyclohexen-1-ol in moderate yields under standard conditions. Introduced by H. L. Riley and coworkers in 1932, the method expanded the utility of selenium-based oxidants beyond simple dehydrogenations to targeted allylic functionalizations. The mechanism proceeds via an where the attacks the electrophilic of SeO₂, forming an allylseleninic acid intermediate that rearranges and to the allylic , with elemental as the byproduct. A simplified representation is: \text{SeO}_2 + \text{R-CH}_2\text{-CH=CH}_2 \rightarrow \text{R-CH(OH)-CH=CH}_2 + \text{Se} This pathway ensures at the allylic position due to the stability of the resulting allylic or cation-like species during rearrangement. Typical reaction conditions involve stoichiometric SeO₂ in a dioxane/ mixture at approximately 80°C, allowing dissolution of the solid reagent and facilitating hydrolysis, though yields can vary with sterics. In pharmaceutical synthesis, the has been applied to construct key intermediates, such as allylic alcohols in precursors derived from β-ionone derivatives, enabling efficient chain extension and functionalization. Similarly, it features in total syntheses, notably the 14-step route to (+)-ingenol from (+)-, where SeO₂ selectively introduces an allylic critical for the diterpenoid's core structure. These applications highlight its role in building pharmacologically active scaffolds like , used in topical cancer treatments. To address selenium's toxicity and improve , catalytic variants employ substoichiometric SeO₂ (5–20 mol%) paired with co-oxidants like tert-butyl hydroperoxide (t-BuOOH), which reoxidizes reduced selenium species back to SeO₂, achieving comparable yields with minimal waste. Post-2010 advancements in have further refined this approach, incorporating solvent-free microwave-assisted conditions or aqueous media to enhance while maintaining selectivity in allylic oxidations.

Industrial and material uses

Selenium dioxide serves as a key additive in glassmaking, primarily as a decolorizing agent to counteract the green tint caused by iron impurities in soda-lime glass. It is typically added in small quantities, around 0.001-0.005% by weight, to produce clear for containers and . In higher concentrations, approximately 0.03-0.1%, it imparts a ruby-red color to through reduction processes. Approximately 20-30% of global selenium consumption, including selenium dioxide, is directed toward the sector for these purposes. In ceramics and enamels, selenium dioxide is employed to generate ruby-red hues upon to , enhancing decorative and functional coatings on and metal substrates. This application leverages its ability to form stable pigments under high-temperature firing conditions. For metal treatment, selenium dioxide is a primary component in cold bluing solutions for , where it reacts in acidic media—often with —to form , promoting surface oxidation and yielding a protective blue-black finish. This process is widely used in firearms and tool manufacturing to prevent without requiring high heat. Selenium dioxide also finds use in photographic toning, converting images to brown tones for improved archival stability and aesthetic enhancement in prints. Due to selenium's and high volatility during processing—where over 75% can be released as emissions—its industrial application has declined in recent years, influenced by stricter environmental regulations on hazardous substances in the and elsewhere.

Other applications

Selenium dioxide serves as a in select , particularly for allylic oxidations and dehydrogenations, offering an alternative to in achieving selective transformations without the need for gaseous . This catalytic role leverages selenium dioxide's ability to abstract hydrogen atoms at allylic positions, enabling milder reaction conditions compared to traditional oxidative methods. In , selenium dioxide functions as a reagent for the determination of selenium content in various samples, often through oxidation and subsequent . It is employed in spectrophotometric methods where it reacts with target analytes to form measurable complexes, allowing for precise quantification in environmental and biological matrices. Additionally, purified selenium dioxide acts as a standard reference material in , such as and UV-visible , due to its well-characterized profiles that aid in calibration and instrument validation. Selenium dioxide is utilized as a precursor in the deposition of thin films for photovoltaic applications, particularly in solar cells, through (CVD) processes. In these methods, it decomposes under controlled thermal conditions to yield elemental selenium layers, which form the basis for absorber materials in thin-film solar technologies like (CIGS) devices. This approach enables the creation of uniform, high-purity films that enhance light absorption and efficiency in next-generation . In , selenium dioxide is incorporated as a trace component in specialized fertilizers designed to address selenium deficiencies in , thereby improving crop nutrition and animal health without excessive supplementation. Its limited use stems from the need for precise dosing to avoid , focusing on seleniferous regions where levels are insufficient for optimal plant uptake and subsequent transfer to the . Such applications support efforts, enhancing selenium content in staple crops like and . Emerging applications post-2020 highlight the potential of selenium dioxide-derived nanoparticles in nanotechnology, particularly for antimicrobial coatings that inhibit bacterial growth on surfaces. These nanoparticles, synthesized via reduction of selenium dioxide, exhibit enhanced biofilm disruption against pathogens like Staphylococcus aureus and Pseudomonas aeruginosa when integrated into polymer matrices such as polyvinyl alcohol. Such coatings show promise for medical devices and food packaging, offering low-fouling properties and sustained antimicrobial efficacy without promoting resistance.

Health, safety, and environmental impact

Toxicity and health effects

Selenium dioxide is highly toxic upon acute exposure, with an oral LD50 in rats reported as 68 mg/kg, indicating significant lethality even at moderate doses. is a particularly hazardous route, causing severe to the ; acute high concentrations (e.g., >1 mg/m³) can lead to . The OSHA PEL is 0.2 mg/m³ as an 8-hour time-weighted average to prevent chronic effects. Symptoms of acute include coughing, , and , progressing to life-threatening fluid accumulation in the lungs if not addressed promptly. Chronic exposure to , resulting in daily intakes exceeding 5 mg, induces selenosis, a condition marked by dermatological and systemic effects such as and brittleness or loss, a characteristic garlic-like on the breath, and gastrointestinal disturbances including and . These symptoms arise from prolonged accumulation of in tissues, disrupting normal physiological processes over time. In occupational environments, where is the predominant exposure pathway, such chronic effects underscore the need for vigilant to prevent cumulative harm. The toxicological mechanism of selenium dioxide primarily involves its rapid hydrolysis in moist environments to form , which mimics sulfur-containing compounds in biological systems. This leads to the incorporation of selenium analogs, such as , into proteins in place of or , thereby altering function and metabolic pathways critical for cellular integrity. Such disruptions particularly affect sulfur-dependent processes, contributing to and protein misfolding. Selenium dioxide holds an IARC classification of Group 3, indicating it is not classifiable as to its carcinogenicity in humans based on available evidence. However, suggest potential , including impaired and developmental effects in offspring following . remains the chief occupational route, with the OSHA PEL set at 0.2 mg/m³ as an 8-hour time-weighted average to mitigate risks. Historical case studies from industrial accidents in the 1970s illustrate the severe consequences of selenium dioxide exposure, where workers inhaling high concentrations during manufacturing processes developed acute due to , often requiring and prolonged recovery. These incidents highlight the compound's capacity for rapid onset of critical health effects in uncontrolled settings.

Environmental considerations

Selenium dioxide released into the oxidizes to selenate under aerobic and alkaline conditions in and , enhancing its and persistence through microbial and chemical processes. This transformation facilitates in aquatic food chains, where selenium concentrations increase across trophic levels via , with trophic transfer factors ranging from 1.2 to 4.6 in and . In , overall can reach factors up to 10 from primary producers to top predators, leading to elevated tissue levels that persist for over a decade in contaminated ecosystems. Ecotoxicity of selenium dioxide is evident in aquatic organisms, with 96-hour LC50 values ranging from 2.9 mg/L for sensitive species like fry to 40 mg/L for more tolerant juveniles. In seleniferous areas, such as the Kesterson Reservoir incident in the , elevated from agricultural (around 300 µg/L) caused severe reproductive impairments in , including deformities and reduced hatching success due to in prey. Industrial emissions, including those from and , contribute approximately 40% of environmental inputs, creating hotspots in and atmospheric systems. Remediation efforts leverage with plants like Astragalus species, which can accumulate up to 1% of dry weight, enhancing removal from contaminated soils through root uptake and microbial . Global monitoring follows EPA's 2021 revised guidelines, prioritizing site-specific tissue criteria (e.g., 8.5 mg/kg dry weight in whole body) with derived chronic concentrations of 1.5 µg/L (lentic) or 3.1 µg/L (lotic) for total recoverable to protect aquatic life. may exacerbate volatilization through rising temperatures and altered microbial activity, potentially increasing atmospheric emissions from soils. Recent post-2020 studies, such as those modeling transport from effluents in the Elk River Valley, demonstrate long-range downstream dispersion up to 575 km, with concentrations rising 35–89% over two decades and loads increasing with distance. As of 2025, the International Joint Commission (IJC) is investigating transboundary pollution from Elk Valley coal mines, with a plan of study released in February 2025 addressing risks over 575 km downstream into U.S. waters.

Handling and regulations

Selenium dioxide requires careful handling to minimize exposure risks due to its and corrosivity. Operations involving this should be conducted in a well-ventilated to prevent inhalation of dust or vapors, with personnel wearing appropriate (PPE) including gloves, safety glasses, protective clothing, and a P3-rated when dust generation is possible. Strict hygiene practices are essential, such as washing hands thoroughly after handling and prohibiting eating, drinking, or smoking in work areas to avoid accidental ingestion. For storage, selenium dioxide should be kept in tightly closed containers in a cool, dry, well-ventilated area with restricted access, as it is hygroscopic and can absorb moisture, potentially leading to decomposition or reduced stability. It is recommended to store the material under an inert atmosphere, such as or , to prevent reactions with air or moisture, and away from incompatible substances like strong reducing agents, , or organic compounds. Sealed containers are preferred to maintain integrity and safety. In the event of a spill, evacuate the area and ensure personnel use full protective gear, including if necessary, while ventilating the space to disperse any . Spilled material should be swept or collected mechanically into covered containers without generating , preventing entry into drains or the environment, and then disposed of as . Transportation of selenium dioxide is regulated as a hazardous material under UN 3283, classified as "Selenium compound, solid, n.o.s. (selenium dioxide)," with Hazard Class 6.1 (toxic substances) and Packing Group III, requiring appropriate labeling, packaging, and documentation for safe shipment by road, rail, air, or sea. Regulatory frameworks address selenium dioxide's hazards comprehensively. In the European Union, under REACH and CLP regulations, it is harmonized as acutely toxic if swallowed (Acute Tox. 3; H301), causing organ damage through repeated exposure (STOT RE 2; H373), and very toxic to aquatic life (Aquatic Acute 1; H400). Notifier classifications additionally include toxic if inhaled (Acute Tox. 2; H330), corrosive to skin (Skin Corr. 1A; H314), and suspected of damaging fertility (Repr. 2; H361). In the United States, it is listed on the TSCA inventory as an active substance, subject to reporting under CERCLA with a reportable quantity of 10 pounds, and falls under EPA hazardous waste code U204 for disposal purposes. OSHA establishes a permissible exposure limit (PEL) of 0.2 mg/m³ as an 8-hour time-weighted average for selenium compounds, including selenium dioxide, measured as elemental selenium. Waste disposal must treat selenium dioxide as , with options including at approved facilities or chemical to followed by stabilization, in compliance with local, national, and international regulations such as those from the EPA to prevent environmental release. Contaminated containers and cleanup materials should be managed similarly without mixing with other wastes. Workers handling selenium dioxide must receive training under OSHA's Hazard Communication Standard (29 CFR 1910.1200), covering the chemical's hazards, safe handling procedures, PPE use, and emergency response, with additional respiratory protection training if exposures exceed the PEL (29 CFR 1910.134). This ensures awareness of toxicity risks, such as those informing risk assessments from exposure limits.

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