Fact-checked by Grok 2 weeks ago

Potassium cyanide

Potassium cyanide is a highly toxic with the KCN, consisting of a potassium cation and a anion, and it appears as a white, deliquescent crystalline solid or amorphous lumps with a faint of bitter almonds. It is highly soluble in , forming a clear, colorless that can contain up to 71.6 g of KCN per 100 mL of at 25 °C, and it has a molecular weight of 65.12 g/mol and a density of 1.52 g/cm³. As a strong and reducing agent, it reacts violently with acids to release gas (HCN), a lethal chemical asphyxiant that binds to in mitochondria, thereby inhibiting cellular oxygen use and causing rapid systemic poisoning. Despite its dangers, potassium cyanide finds industrial applications primarily in gold and silver mining through processes like , where dilute solutions extract precious metals from low-grade ores. It is also used in for silver and other metals, metallurgy for refining and separating , silver, and , as well as in organic chemical synthesis and as a . Production typically involves reacting with or neutralizing hydrocyanic acid with , yielding the salt in crystalline form. The compound's toxicity is profound, with an oral LD50 in mice below 50 mg/kg and a probable lethal dose under 5 mg/kg, leading to symptoms including , vertigo, , rapid breathing, seizures, , and death within minutes via , , or skin . Chronic exposure can cause neurological damage, dysfunction, and cardiovascular effects, necessitating strict handling protocols such as , protective equipment, and antidotes like or in . Due to its potential for misuse in or , potassium cyanide is heavily regulated under international chemical conventions.

Properties

Physical properties

Potassium cyanide appears as a white, crystalline solid, often in granular or powder form. It is hygroscopic and deliquescent, readily absorbing moisture from the air to form a . In pure dry form, it is odorless, but exposure to moist air can produce a faint almond-like smell due to trace formation of . The compound has a molecular weight of 65.12 g/mol and CAS number 151-50-8. Key physical properties are summarized below:
PropertyValue
Melting point634.5 °C
Boiling point1,625 °C (decomposes before boiling)
Density1.55 g/cm³ at 20 °C
Solubility in water68 g/100 mL at 20 °C
Solubility in other solventsSoluble in alcohol and glycerol; insoluble in ether and hydrocarbons
These properties reflect its ionic nature as a salt of and the .

Chemical properties

Potassium cyanide (KCN) is an ionic compound consisting of potassium cations (K⁺) and (CN⁻). In aqueous solutions, it fully dissociates to produce these s, with the acting as a strong capable of attacking electrophilic centers in organic and inorganic reactions. Additionally, CN⁻ functions as an ambidentate , coordinating to metal centers through either the carbon or atom in coordination complexes. The cyanide undergoes in water, establishing an that imparts basicity to KCN solutions: \text{CN}^- + \text{H}_2\text{O} \rightleftharpoons \text{HCN} + \text{OH}^- This reaction results in a of approximately 11 for a 0.1 M , as HCN is a weak with a pKa of 9.21. The linear of the CN⁻ , characterized by a carbon-nitrogen (bond length ≈ 1.16 ), contributes to its reactivity as both a and . KCN exhibits good stability when stored in dry conditions but is sensitive to , , and , which can lead to gradual decomposition. Exposure to acids triggers rapid decomposition, releasing highly toxic gas: \text{KCN} + \text{HCl} \rightarrow \text{KCl} + \text{HCN} In processes, KCN behaves as a . For instance, it reacts with gas to produce (C₂N₂), a toxic gas: $2\text{KCN} + \text{Cl}_2 \rightarrow 2\text{KCl} + (\text{CN})_2 The cyanide ion also forms stable coordination complexes with transition metals, such as the linear [Au(CN)₂]⁻ complex, where CN⁻ binds through the carbon atom.

Crystal structure

Potassium cyanide (KCN) crystallizes in the cubic rock salt structure at room temperature, analogous to , where K⁺ cations and CN⁻ anions occupy the octahedral sites of a face-centered cubic . The space group is Fm\bar{3}m, with the CN⁻ ions exhibiting orientational disorder, randomly aligned along the \langle 111 \rangle directions in the . The unit cell parameter a is 6.523 at ambient conditions, accommodating four formula units per cell. The bonding is predominantly ionic between K⁺ and , though the C–N bond within the cyanide ion displays partial covalent character, with a bond length of approximately 1.17 , consistent with its triple-bond nature. The anion behaves as a pseudohalide in this ionic lattice, contributing to the structural stability despite its linear geometry. No stable polymorphs are observed at standard conditions, but KCN undergoes order-disorder transitions upon cooling: to an orthorhombic structure ( Immm) at around 168 and further to a rhombohedral below 83 , where the CN⁻ ions align preferentially. The cubic persists up to the at 634 °C without additional high-temperature transitions. Infrared spectroscopy reveals a characteristic absorption band at approximately 2080 cm⁻¹ attributed to the C≡N stretching vibration, while diffraction patterns, featuring peaks such as (200) at ~25.5° 2θ (Cu Kα ), serve for structural identification and phase confirmation.

Production

Industrial production

Potassium cyanide is primarily produced industrially by the neutralization of (HCN) gas with (KOH) solution, following the reaction: \text{KOH} + \text{HCN} \rightarrow \text{KCN} + \text{H}_2\text{O} This method, a variant adapted from the Andrussow process for HCN synthesis, involves absorbing HCN in aqueous KOH under controlled conditions to form a concentrated KCN solution, which is then evaporated and crystallized. The HCN feedstock is generated via the catalytic ammoxidation of natural gas (methane), ammonia, and oxygen over platinum-rhodium gauzes at approximately 1,100–1,300 °C: \text{CH}_4 + \text{NH}_3 + 1.5\text{O}_2 \rightarrow \text{HCN} + 3\text{H}_2\text{O} This integrated approach ensures efficient large-scale production, with the process conducted in closed systems to minimize HCN release. The Castner process, originally developed for alkali cyanides, reacts potassium carbonate with carbon and nitrogen (or ammonia) at elevated temperatures (about 1,100 °C): \text{K}_2\text{CO}_3 + 2\text{C} + \text{N}_2 \rightarrow 2\text{KCN} + 3\text{CO} Although historical, this method persists in select facilities due to its simplicity, particularly where or feedstocks are available. Purification typically employs under reduced pressure or recrystallization from aqueous solutions to achieve purities exceeding 95%, removing impurities like carbonates and chlorides. Byproducts such as (CO) and (H₂) from the reactions are captured and managed using gas scrubbers and systems to comply with environmental regulations. Global production of potassium cyanide is estimated at approximately 60,000 metric tons annually in the 2020s, with major manufacturing centered in and the ; as of 2024, global consumption is about 63,000 metric tons, primarily for , with key producers including Chengxin in and Cyanco in the . Facilities employ stringent safety protocols, including automated monitoring and enclosed reactors, to mitigate risks.

Historical production

The precursor to potassium cyanide, (HCN), was first isolated in 1782 by Swedish chemist through the distillation of (iron ) with , yielding a colorless liquid with a bitter almond odor that he termed "blue acid." Scheele also prepared potassium cyanide in 1783, demonstrating its ability to dissolve , which laid early groundwork for its industrial applications. In 1815, French chemist advanced the understanding of cyanide chemistry by confirming the composition of prussic acid as HCN and synthesizing (C₂N₂) from mercuric cyanide via , marking the first isolation of a compound radical. Early production of potassium cyanide relied on the of , a method prevalent in the . This process involved heating (K₄[Fe(CN)₆]) to 600–700 °C, often with as a , following the reaction: \text{K}_4[\text{Fe}(\text{CN})_6] \rightarrow 4\text{KCN} + \text{FeC}_2 + \text{N}_2 The resulting KCN was extracted from the melt. This technique, derived from studies of decomposition, was the primary route for cyanides before 1900. During the , production scaled significantly to meet demand from booms, including the of 1849, where cyanide solutions were explored for ore processing, though widespread adoption came later with the MacArthur-Forrest process in the 1880s. Commercial production began in 1864 in by Hector Roessler at a plant in , later incorporated into Degussa (founded 1873), producing cyanide for export using the method. An alternative early approach fused () with and nitrogen sources to generate cyanide, supporting and needs. The , developed in the 1890s by Hamilton Castner, represented a major advancement through electrolytic production. Initially for via the reaction of sodium with and carbon, it was adapted for potassium cyanide, achieving yields up to 90% by electrolyzing to produce sodium, which was then converted to cyanide. This method reduced costs and impurities compared to thermal processes, facilitating larger-scale output for . In the , production shifted post-World War II toward HCN-based methods, leveraging advances like the Andrussow (methane and oxidation to HCN) for higher efficiency and lower costs. The traditional ferrocyanide decomposition declined by the 1950s as HCN absorption into became standard, reflecting broader industrialization of cyanide manufacturing.

Applications

Gold mining and extraction

Potassium cyanide plays a central role in the -Forrest process, a hydrometallurgical method patented in 1887 by John S. MacArthur, Robert W. Forrest, and William Forrest, for extracting from low-grade s. This cyanidation technique involves treating finely ground ore with a dilute of potassium cyanide, which selectively dissolves gold to form the soluble complex KAu(CN)₂. The key is represented by the equation: $4\text{Au} + 8\text{KCN} + \text{O}_2 + 2\text{H}_2\text{O} \rightarrow 4\text{KAu(CN)}_2 + 4\text{KOH} This process revolutionized gold recovery by enabling efficient extraction from previously uneconomical deposits, particularly refractory ores containing sulfides or tellurides. The extraction begins with crushing the ore to a fine particle size, typically less than 75 micrometers, to maximize surface exposure. The crushed ore is then slurried with a 0.01–0.05% potassium cyanide solution in agitated tanks, maintained at a pH of 10–11 using lime to optimize leaching and prevent cyanide loss as hydrogen cyanide gas. Aeration supplies oxygen to drive the dissolution, with residence times of 24–72 hours yielding the pregnant leach solution containing the gold complex. This solution undergoes solid-liquid separation, followed by adsorption onto granular activated carbon in columns or tanks, where gold loads preferentially. The loaded carbon is eluted with a hot (90–120°C) caustic solution containing 1–2% sodium hydroxide and 0.1–0.2% cyanide, then the rich eluate is processed via electrowinning in electrolytic cells to deposit pure gold cathodes. The MacArthur-Forrest process achieves recovery efficiencies exceeding 90% for non- ores, making it highly effective for large-scale operations. Globally, cyanidation accounts for approximately 70% of production, with annual cyanide consumption in around 1,000,000 tons (primarily as , with potassium cyanide used in specific applications) as of 2023. However, due to environmental regulations, alternatives like or are increasingly adopted as of 2025. For ores resistant to direct cyanidation, alternatives such as or chloride have been developed, but cyanide-based methods dominate due to their cost-effectiveness and established infrastructure. Environmental management includes post-process detoxification of , often via oxidation with /air (INCO process) or to convert cyanide to less toxic or , ensuring compliance with discharge standards.

Electroplating

Potassium cyanide plays a central role in by forming stable metal-cyanide complexes that enable the electrochemical deposition of metals such as and silver onto substrates. These complexes, derived from KCN, dissolve sparingly soluble metals like in aqueous solutions, preventing and while facilitating uniform deposition. The use of cyanide-based baths originated in the 1840s when John Wright discovered that potassium cyanide served as an effective for and silver plating, leading to commercialization by the Elkington brothers. In gold electroplating, potassium cyanide (KAu(CN)₂) is the key compound, prepared by reacting potassium cyanide with chloride or via anodic dissolution of in a cyanide electrolyte. This complex is used in alkaline plating baths for applications in jewelry and electronics, where it provides the source of gold ions. Typical bath compositions include 2-5 g/L KAu(CN)₂, supplemented with free KCN (20-50 g/L) as a buffer to maintain pH and stability, along with conductive salts like potassium carbonate. Operating conditions involve current densities of 0.5-2 A/dm² and temperatures of 50-60 °C to achieve controlled deposition rates. The process entails immersing the (cathode) and a in the ; an drives anodic of the metal into the as the , followed by cathodic and deposition onto the as a bright, adherent layer. Post-deposition, the plated item undergoes thorough rinsing to remove residual . The stabilizes ions against , enabling bright, uniform deposits with excellent throwing power over geometries, and the bath's high tolerance for impurities ensures consistent performance. For silver electroplating, potassium silver cyanide (KAg(CN)₂) is employed similarly, formed from KCN and silver salts, in containing 20-40 g/L of the complex and excess free KCN for buffering. These operate at 20-30 °C and current densities up to 1 A/dm², yielding ductile, reflective silver layers for decorative and electrical contacts. baths for and , using KCu(CN)₂ or K₂Zn(CN)₄ respectively, were historically common for their superior adhesion and coverage on irregular surfaces but have become less prevalent since the 2000s due to stricter environmental regulations on discharge. However, due to environmental regulations, non- alternatives are increasingly adopted as of 2025. Despite environmental concerns over and , potassium cyanide-based remains in use in the 2020s for high-value applications requiring superior deposit quality, such as precision electronics and fine jewelry, where alternatives often compromise performance.

Potassium cyanide serves as a key reagent in various procedures for the qualitative and quantitative determination of cyanide ions and certain metal ions in laboratory settings. In qualitative analysis, Liebig's method, developed in the mid-19th century, detects by titrating the sample with solution, where silver ions react with cyanide to form a white precipitate of according to the equation: \mathrm{Ag}^{+} + \mathrm{CN}^{-} \rightarrow \mathrm{AgCN} This turbidity marks the endpoint, with the method offering accuracy better than 0.2% for alkali cyanides when using iodide as an indicator. In complexometric titrations, potassium cyanide acts as a masking agent to prevent interference from certain metal ions during ethylenediaminetetraacetic acid (EDTA) determinations. It forms highly stable cyanide complexes with ions such as Cu²⁺, Fe³⁺, Zn²⁺, Cd²⁺, Ni²⁺, Co²⁺, Hg²⁺, and Ag⁺, allowing selective titration of other metals like Ca²⁺ or Mg²⁺ without competition from these interferents. For instance, in the analysis of mixtures containing lead, zinc, and aluminum, excess potassium cyanide masks zinc while EDTA complexes the remaining ions, enabling stepwise quantification. This approach is particularly useful in water hardness assessments or alloy compositions where multiple cations are present. Spectrophotometric methods employ to generate cyanide ions for colorimetric detection, often in environmental or industrial samples. The sample is treated with to convert to (CNCl), which then reacts with pyridine-barbituric acid to produce a measurable at 578 nm, providing a suitable for trace analysis down to per liter levels. This follows standardized protocols for waters and extracts, ensuring reproducible results through controlled times of 8-10 minutes. Electrodeposition techniques utilize solutions to facilitate the of metals like , where the complex maintains the metal in solution for controlled cathodic deposition onto a , followed by weighing the deposit for quantification. This method achieves high precision in -base alloys or baths by minimizing co-deposition of impurities. Historically, in 19th-century , -derived supported (HCN) detection in poisoning cases via and subsequent argentometric , aiding investigations of suspicious deaths. For use, is supplied as grade material with purity exceeding 98%, ensuring minimal contaminants that could affect analytical accuracy.

Other industrial uses

Potassium cyanide serves as a key precursor in , particularly for the preparation of nitriles through reactions with alkyl halides. In this process, an alkyl halide (R-X) reacts with potassium cyanide in a polar solvent such as under conditions, yielding the corresponding alkyl nitrile (R-CN) and potassium halide (KX) as a . This method extends the carbon chain by one atom and is widely employed in the of pharmaceuticals, agrochemicals, and other fine chemicals due to its efficiency and versatility. In the production of dyes and pharmaceuticals, potassium cyanide acts as an intermediate by providing cyanide ions that facilitate the formation of key precursors. For indigo dyes, a major component in coloring, cyanide is incorporated during the of phenylglycine, which is subsequently converted to indoxyl and oxidized to ; traditional routes involve reacting with and (generated from potassium cyanide) under alkaline conditions. Similarly, in pharmaceutical manufacturing, nitriles derived from potassium cyanide serve as building blocks for active compounds. For , a critical intermediate in nylon-6,6 production, the process involves hydrocyanation where two molecules of (sourced from cyanide salts like potassium cyanide) add across 1,3-butadiene to form NC-(CH₂)₄-CN, enabling subsequent to . Potassium cyanide has historical application in , where it was used in fixing solutions to dissolve unexposed silver halides from photographic emulsions. Combined with (commonly known as hypo), it enhanced the removal of silver salts, producing clearer images by preventing fogging; however, its use has significantly declined with the advent of and safer alternatives like fixers. In , cyanide salts including are utilized in processes for , particularly cyaniding or . Steel parts are immersed in molten cyanide baths at temperatures around 800–950°C, where carbon and diffuse into the surface layer, forming a hard, wear-resistant case while maintaining a ductile core; this is especially useful for components like gears and tools requiring enhanced durability. Due to environmental concerns and toxicity risks, potassium cyanide's use in these industrial applications has been phased out or restricted in some regions, with eco-friendly alternatives such as glycine-based reagents emerging for certain synthetic processes to minimize cyanide dependency. However, due to environmental regulations, non-cyanide alternatives are increasingly adopted as of 2025.

Health and safety

Toxicity

Potassium cyanide (KCN) exerts its toxic effects primarily through the cyanide ion (CN⁻), which binds irreversibly to the ferric iron in cytochrome c oxidase (complex IV) of the mitochondrial electron transport chain. This binding inhibits the final step of oxidative phosphorylation, preventing electron transfer to oxygen and halting ATP production. As a result, cells shift to anaerobic metabolism, leading to rapid accumulation of lactic acid and the development of lactic acidosis. The overall effect is histotoxic hypoxia, where tissues are unable to utilize oxygen despite adequate supply, causing systemic cellular dysfunction particularly in oxygen-dependent organs like the brain and heart. In acute exposure, KCN is highly potent; the oral LD50 in rats is approximately 5 mg/kg body weight, reflecting its rapid absorption and action. For humans, the estimated is about 1-2 mg/kg (expressed as CN⁻), equivalent to roughly 200 mg for an average adult, with death occurring within minutes due to cardiovascular and respiratory collapse. Upon in acidic environments, such as the , KCN generates (HCN) gas, which is approximately 35 times more toxic than on a concentration-time basis in fire scenarios, due to its faster inhibition of . Chronic low-level exposure to KCN can lead to thyroid inhibition, as its metabolite thiocyanate competes with iodide for uptake by the sodium-iodide in the , potentially causing goiter or . Repeated sublethal doses may also result in neurological damage, including Parkinsonian symptoms such as bradykinesia and lesions, stemming from prolonged histotoxic effects on neural tissues. Compared to (NaCN), KCN exhibits higher (71 g/100 mL versus 48 g/100 mL at 25°C), facilitating quicker and gastrointestinal absorption, which may accelerate its toxic onset.

Exposure risks and symptoms

Potassium cyanide (KCN) can enter the body through multiple routes of exposure, primarily of (HCN) gas released when KCN reacts with acids or moisture, leading to rapid absorption via the , dermal contact through intact but moist , and ocular exposure via direct contact with the eyes. Acute exposure to high doses of potassium cyanide produces symptoms within minutes, including , , , rapid breathing, and a sensation of or suffocation; these progress rapidly to convulsions, loss of consciousness, , and , potentially resulting in death within 1 to depending on the dose. A characteristic bitter almond-like may be detectable on the breath of affected individuals, though this is perceived by only 60-80% of the due to a in olfactory detection. Chronic low-level exposure to cyanide compounds, including from occupational sources involving potassium cyanide, can lead to symptoms such as fatigue, , , headaches, and thyroid enlargement (goiter) due to interference with iodine uptake. Occupational exposure risks are particularly elevated in operations, where tailings spills can release into the , as well as in laboratories and settings like ; personal protective equipment such as respirators for HCN gas and chemical-resistant gloves is essential to mitigate these hazards. The (TLV) for HCN, relevant to airborne exposures from potassium cyanide, is set at 5 mg/m³ as a ceiling limit by the American Conference of Governmental Industrial Hygienists (ACGIH).

Medical treatment

The initial management of potassium cyanide focuses on rapid removal of the from the exposure source to prevent further absorption, ensuring a safe environment for rescuers. Administer 100% oxygen via a to support oxygenation, and provide if is suspected. Do not induce , as this can increase the of or further exposure, particularly if the patient is unconscious or ingestion occurred more than an hour prior. The preferred antidote is , administered intravenously at a dose of 5 g (typically as two 2.5 g vials diluted in 100-200 mL of normal saline and infused over 15-30 minutes), which directly binds the ion (CN⁻) to form nontoxic , facilitating its renal excretion in urine. has been favored as the first-line therapy since the in many international guidelines due to its efficacy and lower risk of adverse effects compared to older regimens, and it received FDA approval for treatment in 2006. As an alternative or adjunct, especially when is unavailable, the traditional cyanide antidote kit may be used, consisting of (inhaled via ampule breakage), followed by (300 mg IV over 3-5 minutes) and (12.5 g IV over 10-20 minutes). The nitrites induce formation, which has a higher affinity for CN⁻ than , forming cyanmethemoglobin to sequester the toxin; then donates a group, enabling the rhodanese to convert to the less toxic , which is excreted by the kidneys. Emerging research as of 2025 explores redirecting intermediary to mitigate 's effects, potentially offering new adjunct therapies. Supportive care is essential alongside antidotes and includes securing the airway, providing if needed, and administering intravenous fluids to maintain hemodynamic stability; vasopressors such as norepinephrine may be required for persistent . In severe cases, hyperbaric has been employed to enhance oxygen delivery and potentially accelerate cyanide detoxification, though its efficacy remains unproven and it is not routinely recommended. Prompt initiation of , ideally within 30 minutes of , can achieve rates exceeding 70% in many reported cases, underscoring the critical need for immediate intervention.

Environmental and regulatory aspects

Disposal and waste management

Potassium cyanide waste must be handled as a hazardous material under classification UN 1680, requiring specialized treatment to prevent environmental release of toxic ions. Safe disposal begins with neutralization to convert to less harmful compounds. One common method is alkaline chlorination, where the waste is adjusted to a pH greater than 10 before adding gas or ; this oxidizes free (CN⁻) to (OCN⁻) via the reaction: \text{CN}^- + \text{Cl}_2 + 2\text{OH}^- \rightarrow \text{OCN}^- + \text{Cl}^- + \text{H}_2\text{O} The cyanate can then be further hydrolyzed under acidic conditions to carbon dioxide and ammonia. Alternative oxidation methods include treatment with hydrogen peroxide (H₂O₂) or ozone (O₃), which first dimerize cyanide to cyanogen ((CN)₂) and subsequently degrade it to carbon dioxide (CO₂) and nitrogen (N₂). These processes are effective for both free and complexed cyanides, achieving over 97% removal in wastewater streams when combined with pH control above 10. In industrial settings, particularly gold mining, the INCO sulfur dioxide/air process is widely used for large-scale detoxification. This involves adding sulfur dioxide (SO₂), oxygen (O₂), and a copper sulfate (CuSO₄) catalyst to the alkaline waste (pH 9–10.5), forming copper cyanide precipitates and sulfate: $2\text{CN}^- + 2\text{Cu}^{2+} + 2\text{SO}_2 + \text{O}_2 \rightarrow 2\text{CuCN} + 2\text{SO}_4^{2-} The copper cyanide is then oxidized further to cyanate and degraded, reducing total cyanide levels below 1 mg/L. For laboratory-scale disposal, dilute aqueous solutions of potassium cyanide are treated by adding excess bleach (sodium hypochlorite) at pH >10 for at least 30 minutes to form cyanate, followed by acidification to neutralize and release non-toxic gases; solid residues are incinerated in permitted facilities. Before any discharge, treated effluents must meet regulatory limits, such as the EU Mining Waste Directive requiring total cyanide concentrations below 10 mg/L in tailings for facilities starting after May 2008, with stricter national limits for discharges to water (e.g., free cyanide often <0.2 mg/L per BAT examples). In mining operations, electrolysis-based recycling recovers up to 90% of cyanide for reuse, minimizing waste generation.

Regulations and notable incidents

Potassium cyanide is subject to stringent regulations due to its high toxicity. Under the on the Control of Transboundary Movements of Hazardous Wastes and Their Disposal, wastes containing inorganic cyanides, including potassium cyanide, are classified as hazardous and listed in VIII (A4050), requiring prior and strict controls for transboundary shipments to prevent environmental harm. For transportation, the classifies potassium cyanide as a Class 6.1 under 1680, mandating specialized packaging, labeling, and documentation to mitigate risks during global shipping. At the national level, regulations further restrict handling and distribution. , potassium cyanide is listed on the Toxic Substances Control Act (TSCA) inventory and qualifies as a toxic chemical under Section 313 of the Emergency Planning and Community Right-to-Know Act, requiring facilities to report releases exceeding specified thresholds. In the , it is registered under regulation (EC) No 1907/2006, with sales and use limited to authorized industrial applications due to its classification as an acute toxic substance, often requiring permits for purchasers. Many jurisdictions worldwide restrict sales to licensed users, such as verified industrial or research entities, to prevent misuse, with violations punishable under poison control laws. In the mining sector, where potassium cyanide is commonly used for , specific oversight exists to address environmental risks. The International Cyanide Management Code (ICMI), established in 2000 by the and the International Council on Metals and the Environment, provides voluntary standards for safe transport, handling, and disposal, including mandatory third-party audits for signatory operations to verify compliance. As of 2025, the ICMI continues to certify operations, with recent audits ensuring compliance amid growing global adoption. Some regions have imposed outright bans; for instance, voters approved Initiative 137 in 1998, prohibiting new open-pit or silver mining using cyanide heap or vat leaching to protect water resources, a measure codified in state law. Global efforts to phase out non-essential uses continue, with several countries like the and banning cyanide in mining since the early 2000s, promoting alternatives such as leaching amid calls for broader restrictions. Notable incidents underscore the dangers of inadequate regulation. In January 2000, a breach at the Aurul gold mine in , , released approximately 100,000 cubic meters of cyanide-laden wastewater (primarily , akin to potassium cyanide in toxicity) into the Someș and rivers, killing vast numbers of and wildlife across the basin and prompting international . The 2015 Tianjin explosions in involved a storing over 700 tons of —far exceeding legal limits—where blasts and subsequent rainwater mixing released toxic vapors and contaminated nearby waters, contributing to at least 173 deaths and widespread ecological damage. In 2022, a worker at Detour Lake gold mine in died from acute during maintenance on a leaking in the , leading to charges against the operator for violations. A 2020 suicide in involved potassium cyanide purchased , highlighting gaps in e-commerce regulations for toxic chemicals. In 2025, authorities in , , intercepted a shipment of potassium cyanide ordered by a dentist suspected in a plot, prompting renewed of chemical sales. Recent incidents have prompted calls for stricter controls on online purchases of cyanide compounds. In forensic contexts, potassium cyanide has been infamously used in homicides and suicides; the 1982 Chicago Tylenol poisonings saw seven people die after capsules were tampered with lethal doses of the compound, leading to nationwide product reforms including tamper-evident .

References

  1. [1]
    Potassium Cyanide | KCN | CID 9032 - PubChem - NIH
    Potassium Cyanide | KCN or CKN | CID 9032 - structure, chemical names, physical and chemical properties, classification, patents, literature, ...
  2. [2]
    POTASSIUM CYANIDE - CAMEO Chemicals - NOAA
    POTASSIUM CYANIDE is a basic salt and a reducing agent. Reacts with acids of all kinds to generate poisonous hydrogen cyanide gas.
  3. [3]
    Potassium Cyanide: Systemic Agent | NIOSH - CDC
    Potassium cyanide releases hydrogen cyanide gas, a highly toxic chemical asphyxiant that interferes with the body's ability to use oxygen.
  4. [4]
    [PDF] Cyanide Heap Leaching--A Report to the Legislature - WA DNR
    Dec 30, 1994 · Cyanide heap leaching is a process for recovering gold and silver by trickling cyanide solutions through low-grade ore stacked on open-air pads.
  5. [5]
    PRODUCTION, IMPORT/EXPORT, USE, AND DISPOSAL - NCBI - NIH
    The demand for hydrogen cyanide in the United States during 2000 was 1.615 billion pounds, up slightly from 1.605 billion pounds in 1999 (CMR 2001).
  6. [6]
    [PDF] Locating and Estimating Sources of Cyanide Compounds - EPA
    The primary cyanide compounds used in electroplating solutions are sodium or potassium cyanide and the metal cyanide, such as gold and silver cyanide. In some ...
  7. [7]
    [PDF] Toxicological Profile for Cyanide, Draft for Public Comment
    Potassium cyanide is used for electrolytic refining of platinum; fine silver plating, as an electrolyte for the separation of gold, silver, and copper from ...
  8. [8]
    [PDF] POTASSIUM CYANIDE - CAMEO Chemicals
    3.7 Toxicity by Ingestion: Grade 4; LD50 below 50 mg/kg (mice). 3.8 Toxicity by Inhalation: Currently not available. 3.9 Chronic Toxicity: None. 3.10 Vapor ...
  9. [9]
    potassium cyanide - CAMEO Chemicals - NOAA
    Probable oral lethal dose in humans is less than 5 mg/kg ... Signs and Symptoms of Acute Potassium Cyanide Exposure: Signs and symptoms of acute exposure ...Missing: LD50 | Show results with:LD50
  10. [10]
    [PDF] Toxicological Profile for Cyanide, Draft for Public Comment
    When six rats were treated with 4 mg CN-/kg as potassium cyanide, signs of CNS toxicity were observed (Ahmed and Farooqui 1982), and cyanide levels 1 hour after.
  11. [11]
    HEALTH EFFECTS - Toxicological Profile for Cyanide - NCBI - NIH
    An average fatal concentration for humans was estimated as 546 ppm hydrogen cyanide after a 10-minute exposure (DOA 1976, as cited in Ballantyne 1988). In one ...DISCUSSION OF HEALTH... · MECHANISMS OF ACTION · BIOMARKERS OF...
  12. [12]
    [PDF] The Facts about Cyanides - New York State Department of Health
    What are the properties of cyanide? There are several chemical forms of cyanide. Hydrogen cyanide is a pale blue or colorless liquid at room temperature and is ...
  13. [13]
    NIOSH Pocket Guide to Chemical Hazards - Potassium cyanide (as ...
    Potassium salt of hydrocyanic acid White, granular or crystalline solid with a faint, almond-like odor.
  14. [14]
    Potassium cyanide - CAS Common Chemistry
    Density (2). 1.55 g/cm³ @ Temp: 20 °C. Source(s). (1) International ... Other Names for this Substance. Potassium cyanide (K(CN)); Potassium cyanide ...
  15. [15]
    Potassium cyanide CAS 151-50-8 | 104965 - Merck Millipore
    Potassium cyanide CAS 151-50-8 EMPLURA® - Find MSDS or SDS, a COA, data sheets and more information.
  16. [16]
    https://www.merckmillipore.com/INTL/en/product/Potassium-cyanide%2CMDA_CHEM-104965
  17. [17]
    https://www.sigmaaldrich.com/US/en/product/mm/104965
  18. [18]
    [PDF] Condensations of Aldehydes and Ketones Catalyzed by Potassium ...
    The solution lame yellow, then orange, then red ... Since potassium cyanide is the salt of a weak acid and a strong base, its solutions are highly basic.
  19. [19]
    [PDF] Chemical Bonding and Molecular Geometry
    cyanide ion (CN. –. ): Writing Lewis Structures with the Octet Rule. For very simple molecules and molecular ions, we can write the Lewis structures by merely ...
  20. [20]
    Properties of solid potassium cyanide - American Institute of Physics
    that the shear elastic constant CH softens dramatically as the crystal is cooled below room temperature; a phenomenon related to the elastic softening is ...
  21. [21]
    [PDF] Neutron scattering study of the orientational disorder in potassium ...
    From 168 K up to its melting point, KCN has the well-known rock salt structure with space group Fm3m [23, 24]. The cyanide anions occupy sites of the full ...
  22. [22]
    Single Crystal Neutron Diffraction Study of Potassium Cyanide
    Apr 1, 1972 · All the reflections observed were consistent with the 6.523‐Å fcc lattice parameter at room temperature determined from the x‐ray data and with ...Missing: group | Show results with:group
  23. [23]
    Photoelectron spectroscopy of CN−, NCO−, and NCS
    Jan 15, 1993 · For NCO− this yields R0(C–N)=1.17±0.01 Å and R0(C–O)=1.26±0.01 Å, and for CN− the equilibrium bond length is found to be Re(C–N)=1.177±0.004 Å.
  24. [24]
    Neutron diffraction study of the structure and phase transitions of ...
    Jun 1, 1977 · The structures of sodium and potassium cyanide have been studied by neutron powder diffraction as a function of temperature between 6 and 300 K.
  25. [25]
    https://pubs.aip.org/aip/jcp/article/66/11/5147/775062/Neutron-diffraction-study-of-the-structure-and
  26. [26]
    [PDF] Standard x-ray diffraction powder patterns: section 18
    lattice parameter of 8.150 A would be expected for lines below 100° 26 ... potassium cyanide, AuK(CN)2 •. 8m. 36. Gold tin, AuSn. 7. 19. Gold titanium, AuTi3.Missing: 5.35 | Show results with:5.35
  27. [27]
    Ammoxidation of Methanol to Hydrogen Cyanide - ACS Publications
    Jul 23, 2009 · Hydrogen cyanide is produced by ammoxidation of methanol using FeMo or MnP oxide catalysts. FeMo produces HCN, while MnP produces methylamine, ...
  28. [28]
    Potassium Cyanide Market By Application (Gold ... - Reports and Data
    The global potassium cyanide market was valued at approximately USD 1.25 billion in 2024, with an estimated global consumption of 63,000 metric tons, and is ...
  29. [29]
    Prussian Blue: Discovery and Betrayal – Part 4 - ChemistryViews
    Aug 2, 2022 · In 1815, Gay-Lussac proved that the composition of “blue acid” was HCN [27]. The original details of the composition he proposed have to be ...
  30. [30]
    https://www.chemistryviews.org/prussian-blue-discovery-and-betrayal-part-4/
  31. [31]
    History - CyPlus GmbH
    With the development of the Castner process the “cyanide eggs”, a product known all over the world, were produced by Degussa's Frankfurt Plant II. 1864.
  32. [32]
    US403202A - Xjohn s stewart macarthur - Google Patents
    Any cyanide soluble in water may be used such as ammonium, barium, calcium, potassium, or sodium cyanide, or a mixture of any two or more of them. \Ve regulate ...Missing: cyanidation | Show results with:cyanidation
  33. [33]
    Alternatives to cyanide in the gold mining industry - ScienceDirect.com
    ... 0.01–0.05% cyanide (100–500 parts per million), are used in tank leaching and heap leaching processes. Cyanide ions (CN−) are the active ingredients in the gold ...Missing: KCN | Show results with:KCN
  34. [34]
    Ultimate Guide for Gold Cyanidation Process - LinkedIn
    Usually lime is added to make the pH value stays 10-11 (protective base). When the pulp pH is more than 11.5, it is not good for gold leaching.
  35. [35]
    Gold CIL & CIP Gold Leaching Process Explained CCD
    Jan 3, 2013 · CIL stands for carbon-in-leach. This is a gold extraction process called cyanidation where carbon is added to the leach tanks (or reaction vessel)
  36. [36]
    Advancements in improving gold recovery from refractory gold ores ...
    Sep 22, 2025 · While non-refractory gold ores yield gold recoveries >90% by simple cyanidation and/or gravity concentration, refractory gold ores are mostly ...
  37. [37]
    Technologies | EnviroLeach Technologies Inc.
    The gold mining sector uses approximately 66,000 tons of sodium cyanide annually worldwide. ... Approximately 20,000 individual tests and assays have been ...
  38. [38]
    [PDF] cyanide destruction | sgs
    Cyanide destruction is required by law in gold plants before discharge. Methods include chlorination, hydrogen peroxide, SO2/Air, and ferrous sulphate ...
  39. [39]
    History of Electroplating - Sharretts Plating Company
    ... cyanide as an electrolyte for electroplating. In 1840, Wright began working with the Elkington cousins, George and Henry, who bought Wright's patent and ...
  40. [40]
    [PDF] Gold Plating - Surface Technology Environmental Resource Center
    The plating solutions employed usually contain potassium gold cyanide, KAu(CN)2, sometimes re- ferred to as PGC. Solution conductivity and buffering are.
  41. [41]
    Basics of Gold and Silver Plating - Finishing and Coating
    Jan 9, 2024 · Trivalent gold cyanide solutions have also been used in jewelry plating to deposit very bright, adherent layers up to about 5 microns thickness.
  42. [42]
    [PDF] Electrochemical preparation of potassium gold cyanide
    The electrochemical method depends on the direct anodic dissolution of gold in cyanide solution (Blum and Hogaboom 1958; Visco 1974). Excepting for the.
  43. [43]
    Cyanide Bath - an overview | ScienceDirect Topics
    A cyanide bath is defined as a toxic solution used in zinc electroplating, consisting of sodium sulfate, sodium hydroxide, and proprietary brightening ...
  44. [44]
    [PDF] Silver Plating
    The principal toxic materials involved in silver plating are potassium cyanide, silver cyanide, and potassium silver cya- nide. When handling these salts ...
  45. [45]
    [PDF] The analysis of cyanide silver-plating solutions
    (The origin of curve B is displaced 5 ml to the right of A.) When potassium iodide is present in the titrated solution, reaction. KI + AgN03 = Agl + KN03. (3).
  46. [46]
    ASSAY FOR CYANIDE BY TITRATION WITH SILVER NITRATE
    Feb 6, 2018 · ... silver nitrate will react with the double cyanide forming silver cyanide, which separates as a white precipitate and renders the solution turbid ...Missing: Liebig history
  47. [47]
    [PDF] Objectives COMPLEX FORMATION TITRATION
    Some metal ions that interfere in EDTA titrations can be masked by addition of a suitable masking agent . For example, cyanide ion can be used to mask certain ...
  48. [48]
    Selective masking and demasking for the stepwise complexometric ...
    The determination is carried out using potassium cyanide to mask zinc, and excess disodium salt of EDTA to mask lead and aluminium. The excess EDTA was ...
  49. [49]
    [PDF] Method 9014: Cyanide in Waters and Extracts Using Titrimetric and ...
    a basic starting point for generating its own detailed standard operating ... 7 Working standard potassium cyanide solution (1 mL = 10 μg CN−), KCN.
  50. [50]
    Potassium cyanide, 98+%, for analysis, Thermo Scientific Chemicals
    Potassium cyanide, 98+%, for analysis, Thermo Scientific Chemicals from Thermo Scientific Chemicals. Shop Potassium cyanide, 98+%, for analysis, ...
  51. [51]
    Electrogravimetry - an overview | ScienceDirect Topics
    Electrogravimetry is defined as a method that quantitatively determines the amount of metal electroplated onto an electrode, typically by measuring the weight ...
  52. [52]
    Preparation of Nitriles - Chemistry LibreTexts
    Jan 22, 2023 · Making nitriles from halogenoalkanes. The halogenoalkane is heated under reflux with a solution of sodium or potassium cyanide in ethanol.Missing: precursor | Show results with:precursor
  53. [53]
    Enzymatic synthesis of indigo-derivative industrial dyes
    In USA the phenylglycine is obtained by reacting formaldehyde, cyanide, aniline, and potassium hydroxide.
  54. [54]
    Chapter 17. Fixing Solutions
    Fixing solutions consist of chemical substances that dissolve the sensitized salts of silver on plates or paper, on which photographic images have been ...Missing: hypo | Show results with:hypo
  55. [55]
    Heat treatment techniques overview | Thermal Processing Magazine
    Cyaniding or pack cyanide carburizing is used to case harden steel. It generates a very thin but hard outer case. Cyaniding is a case-hardening process in ...
  56. [56]
    Glycine/Glutamate: “Green” Alternatives to Recover Metals from ...
    Dec 23, 2022 · Several studies using glycine have been related to gold dissolution as an alternative to traditional cyanide or as a mixed cyanide/glycine ...
  57. [57]
    Cyanide Toxicity - StatPearls - NCBI Bookshelf - NIH
    Feb 22, 2025 · Cyanide toxicity is a rare but often fatal poisoning that occurs through ingestion, inhalation, dermal absorption, or injection.Missing: LD50 | Show results with:LD50
  58. [58]
    [PDF] Understanding the Toxic Twins: HCN and CO
    Studies have shown that in fire smoke, hydrogen cyanide can be up to 35 times more toxic than carbon monoxide. Because of the extreme toxicity of HCN, ...
  59. [59]
    https://www.ncbi.nlm.nih.gov/books/NBK507796/
  60. [60]
    Medical Management Guidelines for Hydrogen Cyanide - CDC
    Hydrogen cyanide is highly toxic by all routes of exposure and may cause abrupt onset of profound CNS, cardiovascular, and respiratory effects, leading to death ...
  61. [61]
    RELEVANCE TO PUBLIC HEALTH - Toxicological Profile for Cyanide
    Jul 2, 2006 · Chronic exposure to lower cyanide concentrations in occupational settings causes a variety of symptoms from fatigue, dizziness, and headaches ...
  62. [62]
    Guidelines for Cyanide - NCBI - NIH
    Chronic exposure to cyanide can result in neuropathies, goiter, and diabetes ... Workers exposed to cyanide gas and alkali cyanide salts via inhalation had mean ...
  63. [63]
    [PDF] Toxicological Profile for Cyanide, Draft for Public Comment
    The ATSDR toxicological profile succinctly characterizes the toxicologic and adverse health effects information for these toxic substances described therein ...
  64. [64]
    [PDF] Cyanide Compounds - U.S. Environmental Protection Agency
    Cyanide is extremely toxic to humans. Chronic (long-term) inhalation exposure of humans to cyanide results primarily in effects on the central nervous system ( ...
  65. [65]
    Hydrogen cyanide - IDLH | NIOSH - CDC
    Current OSHA PEL: 10 ppm (11 mg/m3) TWA [skin]. 1989 OSHA PEL: 4.7 ppm (5 mg/m3) STEL [skin]. 1993-1994 ACGIH TLV: 10 ppm (11 mg/m3) CEILING [skin].
  66. [66]
    Cyanide Toxicity Treatment & Management - Medscape Reference
    May 12, 2025 · Available antidotes are hydroxocobalamin (Cyanokit) and sodium thiosulfate/sodium nitrite (Nithiodote). Both are given intravenously.Approach Considerations · Prehospital Care · Cyanide Antidotes · Transfer
  67. [67]
    Hydroxocobalamin - StatPearls - NCBI Bookshelf
    May 29, 2023 · Hydroxocobalamin is a medication used in the management and treatment of vitamin B12 deficiency and acute cyanide toxicity.Continuing Education Activity · Indications · Mechanism of Action · AdministrationMissing: protocol | Show results with:protocol<|control11|><|separator|>
  68. [68]
    Hydroxocobalamin • LITFL • Toxicology Library Antidotes
    Nov 3, 2020 · Reconstitute 1 ampoule (2.5g) with 100ml of 0.9% saline. Administer IV over 15 minutes. Repeat the process with the second ampoule. This should ...Missing: protocol | Show results with:protocol
  69. [69]
    Cyanokit (hydroxocobalamin) FDA Approval History - Drugs.com
    FDA Approved: Yes (First approved December 15, 2006) ; Brand name: Cyanokit ; Generic name: hydroxocobalamin ; Dosage form: Injection ; Company: EMD Pharmaceuticals ...
  70. [70]
    Cyanide Antidotes - CHEMM
    Sodium nitrite should be administered first, followed immediately by sodium thiosulfate. Blood pressure must be monitored during infusion in both adults and ...<|separator|>
  71. [71]
    Acute Cyanide Poisoning: Hydroxocobalamin and Sodium ...
    The absorbed cyanide is primarily metabolized through the liver with an enzyme called rhodanese that catalyzes the conversion of cyanide to thiocyanate. This ...
  72. [72]
    https://chemm.hhs.gov/antidote_cyanide.htm
  73. [73]
    Acute cyanide Intoxication: A rare case of survival - PMC - NIH
    It is rapidly absorbed, symptoms begin few seconds after exposure and death usually occurs in <30 min. The average lethal dose for potassium cyanide is about ...
  74. [74]
    [PDF] Cyanide Waste Treatment - Hach
    First, the pH is adjusted and controlled to be 10 pH or higher by adding caustic. NOTE: This is a very important step because dangerous cyanogen chloride (CNCI) ...
  75. [75]
    Cyanide Destruction Methods and Processes - 911Metallurgist
    Jul 7, 2016 · Cyanide oxidation with ozone is a two-step reaction similar to alkaline chlorination. Cyanide is oxidized to cyanate, with ozone reduced to ...
  76. [76]
    Effective Cyanide Removal from Industrial Wastewater | Spartan
    Treatment of cyanide bearing wastewater has been carried out with ozone, hydrogen peroxide, alkaline chlorination (either with chlorine, hypochlorite or on-site ...Missing: methods potassium<|separator|>
  77. [77]
    [PDF] CYANIDE DETOXIFICATION: INCO SULFUR DIOXIDE/AIR PROCESS
    Aug 11, 1993 · INCO's process is patented and requires a license to operate. The associated licensing fee is determined on a site specific basis.Missing: CuSO4 | Show results with:CuSO4
  78. [78]
    [PDF] A review of cyanide destruction processes from laboratory and plant ...
    Some of the most commonly implemented cyanide detoxification processes include the INCO process (SO2/air) using sodium ... of copper sulphate (CuSO4.5H2O) ...
  79. [79]
    [PDF] EHS Program Manual 5.2 - Waste Disposal Procedure
    Contact Time: An appropriate contact time of sodium hypochlorite with liquid waste is 30 minutes or overnight before disposal. ... Potassium cyanide K(CN). P098.
  80. [80]
    Industrial Wastewater Discharge Limits and Requirements - LiqTech
    Industrial Wastewater Discharge Limits and Regulations in Germany ; 0.1 mg/l, annual volume of 15 kg · 5 mg/l, annual volume of 125 kg · 100 µ/l, annual volume of ...
  81. [81]
    An electrogenerative process for the recovery of gold from cyanide ...
    The system resulted in more than 90% gold being recovered within 3 h of operation. Activated RVC serves as a superior cathode material having the highest ...
  82. [82]
    “List A” (“Amber control procedure”) of wastes according to the Basel ...
    A4050, Wastes that contain, consist of or are contaminated with any of the following: Inorganic cyanides, excepting precious-metal-bearing residues in ...
  83. [83]
    [PDF] POTASSIUM CYANIDE HAZARD SUMMARY IDENTIFICATION ...
    CONSULT THE NEW JERSEY. DEPARTMENT OF HEALTH AND SENIOR SERVICES. HAZARDOUS SUBSTANCE FACT SHEET ON. HYDROGEN CYANIDE. IDENTIFICATION. Potassium Cyanide is a ...
  84. [84]
    Potassium cyanide (K(CN)) - Substance Details - SRS | US EPA
    Systematic Name: Potassium cyanide (K(CN)) EPA Registry Name: Potassium cyanide Comptox DTXSID: DTXSID0024268 Internal Tracking Number: 40261
  85. [85]
    Potassium cyanide - Registration Dossier - ECHA
    Manufacture, use & exposure; Physical & Chemical properties; Environmental fate & pathways; Ecotoxicological information; Toxicological information; Analytical ...
  86. [86]
    Few Regulations Limit Cyanide's Use or Sale - The Washington Post
    Oct 4, 1982 · "You would have to control the sale of the substance in all instances." Cyanide is also subject to regulation by EPA under the Pesticide ...Missing: licensed | Show results with:licensed
  87. [87]
    The Cyanide Code: Home
    The Cyanide Code is intended to promote and help ensure the safe and environmentally responsible management of cyanide used within the gold and silver mining ...Signatory Directory · Training · Auditing · About Us
  88. [88]
    Should cyanide still be used in modern-day mining?
    Mar 7, 2016 · The use of cyanide in mining operations is facing increasing public opposition with some countries banning it completely.
  89. [89]
    Cyanide Spill at Baia Mare Romania - UNEP/OCHA Assessment ...
    Mar 31, 2000 · On 30 January 2000, following a breach in the tailing dam of the Aurul SA Baia Mare Company, a major spill of cyanide-rich tailings waste was ...
  90. [90]
    China: Sodium cyanide levels well past limit at Tianjin explosion site
    Water tests show high levels of sodium cyanide, an extremely toxic chemical that can kill humans rapidly, at eight locations at the blast site.
  91. [91]
    How the 1982 Tylenol Poisonings Nearly Canceled Halloween
    Oct 3, 2022 · Someone had opened the capsules and replaced the pain-relieving medicine with deadly doses of potassium cyanide. ... “[The 1982 Tylenol poisonings] ...