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Mond process

The Mond process, also known as the carbonyl process, is a vapor-phase metallurgical used to high-purity (>99%) from impure nickel sources, such as or , by forming and selectively decomposing volatile (Ni(CO)4). Developed by German-born Ludwig Mond in the late , the process leverages the unique reactivity of with (CO) to separate it from impurities like , , iron, , and precious metals, which remain in the solid residue. First observed in 1884 when Mond noted the corrosive effect of hot CO on , the method was patented in 1890 and achieved commercial viability by 1902, revolutionizing production for industrial applications including alloys, stainless steels, batteries, and . The process begins with the reduction of () using a mixture of and at approximately 200°C to yield impure nickel metal, followed by with excess at 50–60°C and 1–5 pressure to form gaseous Ni(CO)4 via the Ni + 4CO → Ni(CO)4. The volatile Ni(CO)4—a colorless, highly toxic liquid boiling at 42.2°C—is then separated from non-volatile impurities through distillation or selective volatilization, often in rotating batch reactors at pressures up to 1 MPa. Finally, the purified Ni(CO)4 is heated to 180–250°C in a decomposer, where it thermally dissociates according to Ni(CO)4 → Ni + 4CO, depositing pure as powder or pellets on heated surfaces while recycling the for reuse. This closed-loop approach, operational for over a century primarily in Canada and the UK, ensures exceptional purity (up to 99.998%) but requires stringent safety measures due to the extreme toxicity of Ni(CO)4, with exposure limits as low as 1 part per billion in air.

History and Development

Discovery of Nickel Carbonyl

In 1889, while investigating the unexpected of components in industrial equipment for , Ludwig Mond and his assistant Carl Langer observed unusual effects caused by residual (CO) in the gas stream. The surfaces developed a peculiar mirror-like deposit on nearby glassware, and the metal appeared to dissolve, forming a volatile, colorless liquid that aggressively etched the glass. This serendipitous observation, occurring in Mond's laboratory at his home in London, revealed the formation of nickel tetracarbonyl, Ni(CO)4, a highly toxic and reactive compound that explained the damage to lab equipment through its volatility and chemical aggressiveness. To systematically study this phenomenon, Mond and Langer conducted controlled experiments by passing purified over finely divided powder in a apparatus at moderate temperatures around °C. The proceeded as + 4 → Ni(CO)4, yielding the tetracarbonyl as a that could be distilled at low temperatures, confirming its high volatility with a boiling point of approximately 43°C. These initial trials demonstrated the compound's stability under ambient conditions but also its hazardous nature, as inadvertent exposure led to symptoms resembling poisoning among laboratory personnel, underscoring its toxicity. The findings were first reported in a seminal paper co-authored with Friedrich Quincke, detailing the synthesis and basic properties of this novel organometallic compound. Mond subsequently collaborated with chemist Pattinson to further characterize nickel tetracarbonyl's , focusing on its and thermal reversibility. Their joint experiments revealed that the compound decomposed back into pure nickel and CO upon heating to around 150–200°C, depositing nickel as a coherent mirror on cooler surfaces—a process that highlighted the reaction's potential for purification. This work, published in , expanded on the initial discovery by quantifying the compound's behavior under varying conditions, establishing Ni(CO)4 as a key intermediate in nickel chemistry and paving the way for its industrial application.

Invention and Patenting

Following the discovery of nickel carbonyl, Ludwig Mond developed a practical method for utilizing the compound to purify , filing a British patent application on 12 August 1890 that detailed the extraction and separation of from ores and impure metals. The patent outlined a for converting impure —contaminated with elements such as and iron—into volatile nickel carbonyl by reaction with , followed by decomposition to yield high-purity , thereby enabling effective separation of from non-volatile impurities that do not form similar compounds under the specified conditions. In the ensuing years of the , Mond and his collaborators refined the technique through experimental adjustments to operational parameters, particularly optimizing to approximately 50°C and applying controlled to enhance the efficiency and yield of carbonyl formation while minimizing side reactions. These improvements addressed challenges in and purity, building on initial observations to make the process viable for application, as documented in contemporary reports. To commercialize the refined process, Mond established the Mond Nickel Company on 30 September 1900, with initial capital focused on acquiring resources and constructing refining facilities. The company's first plant, located in Clydach near , , began operations in 1902, marking the inaugural large-scale implementation of the carbonyl-based purification method and processing imported matte from Canadian sources.

Industrial Implementation

The Mond process achieved its first industrial implementation with the establishment of the Mond Nickel Company's refinery at Clydach, near , , in 1902. This facility processed nickel matte shipped from Canadian copper-nickel mines in the region of , applying the patented carbonyl volatilization technique to separate and purify from impurities like and . The plant's design incorporated large-scale reactors for the formation and decomposition of nickel carbonyl, enabling the production of high-purity pellets suitable for industrial applications. By the 1920s, the Mond Nickel Company had expanded its operations to multiple sites, including mining and refining facilities in to secure raw material supplies closer to source, and the process was implemented at refineries in , such as those operated by Falconbridge Nikkelverk in , which refined imported using the carbonyl method. This geographic diversification supported increased production capacity and reduced transportation costs for Canadian ores. At its peak in the late 1920s, following the merger with the International Nickel Company of , the combined operations accounted for over 90% of global supply, underscoring the process's pivotal role in meeting surging demand from emerging industries like alloying and . Industrial scaling of the Mond process encountered major challenges from the extreme toxicity of and nickel carbonyl, both of which posed severe risks of acute through or in early open-air setups. These hazards prompted innovations in , including the adoption of fully enclosed reaction vessels and piping systems to contain gases, along with controls and monitoring protocols to limit worker exposure. Such advancements were critical for enabling safe, continuous operation and facilitating the process's growth into a cornerstone of early 20th-century nickel .

Chemical Principles

Formation Reaction

The formation reaction in the Mond process involves the selective carbonylation of impure nickel metal with carbon monoxide to produce gaseous nickel tetracarbonyl, which enables the purification of nickel by volatilization. The primary reaction is given by: \mathrm{Ni(s) + 4\, CO(g) \rightleftharpoons Ni(CO)_4(g)} This equilibrium reaction occurs at atmospheric pressure and temperatures typically between 50–60°C (323–333 K), where the forward formation is favored due to the exothermic nature of the process. Nickel tetracarbonyl, Ni(CO)₄, is a colorless, volatile compound with a boiling point of 43°C, rendering it gaseous under the reaction conditions at 50–60°C and 1 atm, which facilitates its separation from solid residues. Carbon monoxide serves dual roles as both a reactant in the carbonylation and as a carrier gas, promoting the transport of the volatile Ni(CO)₄ away from the reaction site while maintaining the necessary partial pressure for equilibrium. The reaction proceeds on the surface of finely divided or powdered impure nickel, often derived from reduced nickel oxide feedstocks, with kinetics enhanced by the high surface area and mild heating. The selectivity of the formation reaction is crucial for purification, as common impurities such as iron and do not form stable, volatile carbonyl compounds under these conditions and thus remain as non-volatile solid residues. For instance, while iron can form Fe(CO)₅, it decomposes rapidly above 42°C (315 K), preventing its accumulation in the gas phase at the process temperature. , lacking a stable mononuclear carbonyl under and moderate temperatures, exhibits negligible reactivity with in this context, ensuring that over 99% of the is extracted while impurities are rejected. This mechanism underpins the Mond process's ability to achieve high-purity nickel recovery from complex ores.

Decomposition Reaction

The decomposition reaction in the Mond process is the breakdown of , Ni(CO)4, which yields pure metal and gas. This step reverses the reaction and occurs at temperatures between 150°C and 200°C, following : \ce{Ni(CO)4 (g) ->[150-200^\circ C] Ni (s) + 4CO (g)} In the industrial decomposer, vapor is introduced into a heated chamber containing pellets, typically 1 mm in diameter, preheated to the temperature. The carbonyl decomposes heterogeneously on the pellet surfaces, depositing atoms layer by layer to form dense, high-purity "shot" with greater than 99.9% purity; this process is repeated approximately 300 times per pellet, growing them to about 10 mm in diameter. The carbon monoxide byproduct is separated from residual nickel carbonyl, purified to high levels (typically >99% purity), and recycled to the formation step, achieving near-complete reuse and minimizing gas consumption in the overall process.

Thermodynamic and Kinetic Aspects

The Mond process relies on the reversible formation and decomposition of nickel tetracarbonyl, governed by thermodynamic favorability that shifts with temperature. For the formation reaction, the standard Gibbs free energy change (ΔG°) is given by ΔG° = -163681 - 12.5T ln T + 490.1T J/mol, where T is in Kelvin, resulting in negative values at low temperatures (e.g., below approximately 390 K at 1 atm), favoring carbonyl production, and positive values at higher temperatures, promoting decomposition. This temperature-dependent reversibility is underpinned by an exothermic enthalpy change (ΔH ≈ -160 kJ/mol), calculated from the standard enthalpy of formation of Ni(CO)₄(g) at -602.5 kJ/mol and that of CO(g) at -110.5 kJ/mol, enabling the process to separate nickel via selective volatilization at moderate conditions. Kinetically, the formation of nickel tetracarbonyl exhibits a low activation barrier, particularly when trace impurities act as catalysts to accelerate the surface reaction, with maximum rates observed around 348 K under typical conditions. In contrast, decomposition requires higher activation energy, approximately 99.6 kJ/mol (23.8 kcal/mol), reflecting the need for thermal input to overcome the energy barrier for the reverse process, which proceeds via a unimolecular decay mechanism involving bond elongation. These kinetic differences ensure efficient carbonyl generation at lower temperatures and controlled deposition at elevated ones, with industrial operations maintaining precise temperature gradients (e.g., 315–390 K for formation and above 448 K for decomposition) to optimize yields. Pressure plays a critical role through , as the formation reaction consumes three moles of gas per mole of carbonyl (Δn_gas = -3), shifting equilibrium toward the carbonyl at elevated CO s; for instance, at 373 K, the of Ni(CO)₄ rises from 0.60 at 1 total to nearly 9.86 at 10 , enhancing conversion efficiency. This dependence allows the process to operate effectively under moderate conditions while minimizing costs for gas .

Process Description

Feedstock Preparation

The feedstock for the Mond process primarily consists of (NiO), obtained through the of nickel mattes derived from sulfide ores such as . Nickel mattes, produced via of concentrates, historically contained around 30-50% along with significant amounts of and iron sulfides, while modern mattes often contain 65-80% ; roasting converts them to oxides. This is reduced to impure metallic in a using gas or —a mixture of approximately equal parts and —at temperatures ranging from 200°C to 300°C. The occurs in towers or , where the oxide is heated to remove oxygen, yielding a spongy or granular metallic product. Prior smelting and steps partially eliminate volatile impurities, but the resulting metallic retains contaminants such as (typically 5-10%), iron (up to 10%), , and . To ensure efficient reaction with in the carbonylation step, the reduced is processed into pellets or fine powder, maximizing surface area for gas-solid contact. This preparation involves crushing, grinding, and sometimes briquetting the reduced material.

Carbonylation Step

In the carbonylation step of the Mond process, finely divided impure , obtained from the prior reduction of feedstock, is placed in a reactor and exposed to a stream of pure gas. The reaction occurs at temperatures between 50°C and 60°C under , with bubbled continuously through the nickel bed to facilitate the formation and volatilization of (()4). This step typically proceeds over a period of several hours, such as 6 to 13 hours in optimized setups, allowing for the conversion of 90-96% of the available into Ni(CO)4 vapor, which is then separated from the remaining solid impurities. Unreacted nickel solids are recycled to subsequent batches to maximize efficiency and recovery. Given the high and of Ni(CO)4, which boils at 43°C, the process employs closed-loop systems to recirculate and contain the carbonyl vapor, minimizing exposure risks and enabling safe handling in industrial environments.

Purification and Decomposition

Following the carbonylation step, the crude (Ni(CO)4) vapor is purified via at 40–50°C under reduced , exploiting the compound's of approximately 43°C to separate it from volatile impurities such as iron carbonyl (Fe(CO)5) and other metal carbonyls. This step ensures the removal of contaminants that could otherwise deposit during subsequent processing, yielding a high-purity Ni(CO)4 stream suitable for decomposition. The purified Ni(CO)4 is then fed into heated decomposer towers operated at 180–200°C, where occurs on the surface of pre-heated seed pellets. In this setup, the carbonyl vapor contacts the pellets, depositing successive layers of pure and gradually enlarging them into shot-sized granules, while minimizing through controlled flow and agitation. The decomposition regenerates gas, which is recycled to the stage with over 95% efficiency, supporting the process's closed-loop operation and reducing raw material needs. The output consists of shot with 99.95% purity, and streams are minimal, primarily limited to inert residues from initial feed preparation.

Applications and Advantages

Industrial Uses of Purified Nickel

The Mond process yields nickel with purity levels of 99.9-99.99%, enabling its use in applications requiring minimal impurities. In the early , high-purity was incorporated into nickel steels for armor plating and the emerging production of stainless steels, enhancing their strength and resistance during industrial expansion. High-purity has been utilized in coinage, particularly in alloys (75% copper, 25% ) for circulating coins. In , Mond process nickel serves as a base material for bright nickel deposits, often applied as an undercoat (approximately 20 µm thick) beneath chromium layers on automotive parts, , and consumer goods to improve protection and . For alloys, high-purity nickel is a key component in (a nickel-copper with at least 63% nickel), valued for its resistance to and acids in marine , chemical processing equipment, and fasteners. In electronics, the high purity supports applications in rechargeable batteries (such as cells), catalysts for reactions, and conductive components like lead wires and sparking electrodes. Chemically, it facilitates the production of salts, including sulfate and chloride, used in baths, mordants, and metal finishing, where trace impurities could degrade performance.

Benefits Compared to Other Refining Methods

The Mond process achieves high purity levels for , typically 99.9-99.99%, comparable to electrolytic refining which also reaches 99.99% or higher. This superior refinement occurs without dissolving the metal in an solution, thereby eliminating risks of contamination from impurities that can migrate into the bath during electrolytic processes. A key advantage lies in its energy efficiency, as the process operates at moderate temperatures between 50°C and 250°C, significantly lower than the high-temperature requirements of pyrometallurgical , which often exceed 1000°C. The reversible gas-phase reaction allows for the recycling of , reducing overall energy consumption and material waste compared to energy-intensive alternatives. The process demonstrates high selectivity in impurity removal, particularly for elements like and , which do not form volatile carbonyl compounds and thus remain in the solid residue, enabling cleaner separation than in methods where such impurities persist in the final product. This purity supports applications in high-performance alloys and requiring minimal contamination. As of 2025, the Mond process continues to be used for producing high-purity in applications such as rechargeable batteries for electric vehicles.

Modern Context and Alternatives

Current Usage and Adaptations

The Mond process remains in active use by Vale at its Copper Cliff refinery in , , , and the Clydach Nickel Refinery in , , , where it produces high-purity for specialty applications such as alloys, , and . The facility employs the Inco Pressure Carbonyl (IPC) variant of the process, integrated with upstream and milling operations to refine from sulphide ores, supporting ongoing production amid Vale's broader portfolio. At Clydach, the original site of commercial Mond process implementation since 1902, annual output stands at approximately 40,000 tonnes of refined in forms like powders and pellets as of 2025. These operations play a niche role in supplying high-purity for specialty markets, emphasizing the process's value in delivering ultra-pure metal amid shifting industry demands. Adaptations to the Mond process have focused on enhancing its compatibility with emerging needs, including with hydrometallurgical techniques to battery-grade suitable for applications. In 2025, Vale received provincial funding to develop advanced carbonyl reactor technology at the Copper Cliff complex, enabling the processing of alternative feedstocks like mixed hydroxide precipitates alongside traditional mattes, thereby expanding capacity and versatility. Safety enhancements, implemented following stricter post-2000s regulations on hazardous gases, incorporate automated (CO) monitoring and closed-loop gas recovery systems to mitigate exposure risks in the step, ensuring compliance and operational reliability. Environmental adaptations have prioritized emissions control to meet 2020s targets, with CO emissions reduced through units and efficient gas that recovers over 99% of process CO for . At Clydach, Vale has piloted CO2 capture via bioreactors, converting vent gases into while cutting net emissions, as part of a broader net-zero roadmap by 2050. These upgrades align the process with global decarbonization efforts, maintaining its viability for low-carbon production.

Comparison with Alternative Processes

The Mond process excels in producing ultra-high-purity nickel (>99.99%) from nickel matte, making it suitable for applications requiring minimal impurities, whereas the Sherritt-Gordon process, an ammonia pressure leaching method, is optimized for faster extraction and recovery from bulk low-grade sulfide concentrates and mattes, achieving nickel recoveries of up to 98% in hours under elevated temperatures and pressures. However, the Mond process's vapor-phase carbonylation is slower, involving multi-stage heating and decomposition cycles that limit throughput compared to the Sherritt-Gordon's continuous leaching, which handles larger volumes of lower-grade ores more efficiently but yields nickel powders or salts typically requiring additional refining for equivalent purity. In contrast to electrolytic refining, which deposits high-purity (99.9-99.95%) from slimes containing and byproducts, the Mond process circumvents electricity-intensive and slime management, reducing energy costs and operational complexity for dedicated nickel streams. Yet, the Mond process demands careful handling of toxic gas, posing safety and environmental challenges absent in electrolytic methods, which integrate well with copper-nickel co-production from polymetallic ores like those in or . By 2025, the Mond process's global market share has declined to less than 5% of primary production, constrained by the scarcity of high-grade ores suitable for its feedstock, while processing methods, including high-pressure (HPAL), account for about 70% of global production, particularly in for processing abundant low-grade ores into intermediates. This shift reflects the scalability of -based methods for reserves that comprise 70% of known resources, outpacing -based methods like Mond amid rising demand for EV .

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