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Lithium nitride

Lithium nitride is an with the Li₃N. First synthesized in the late , it is the only stable , notable for its high lithium-ion and role as a in advanced technologies. It appears as a reddish-brown powder and exhibits strong reactivity, particularly with water or moisture, generating corrosive and toxic gas. As a fast ionic with around 10⁻³ S cm⁻¹ at , it has been investigated for applications in lithium-ion batteries and , though its low decomposition potential of approximately 0.45 V limits some uses due to reactivity. The of lithium nitride is hexagonal, belonging to the P6/mmm, featuring two distinct lithium sites: one between nitrogen atoms and another within Li₂N planes, with inherent lithium vacancies of about 3% at . These vacancies contribute to its superionic , with activation energies for lithium ranging from 0.55 to 0.68 , varying by diffusion direction and process. Lithium nitride is highly flammable and acts as a strong , incompatible with oxidizing agents like atmospheric oxygen and violently reactive with acids, especially oxidizing ones; it may ignite spontaneously in moist air. Synthesis of lithium nitride typically involves the direct reaction of metal with gas, often facilitated by using liquid sodium as a to control the process. It can also be deposited as coatings via reactive magnetron in Ar/N₂ atmospheres for thin-film applications. Derivatives, such as transition-metal-doped variants like Li₃₋ₓ₋ᵧMₓN (where M = or ), are prepared by reacting lithium nitride with metals under nitrogen, resulting in structures analogous to the parent compound but with higher vacancy concentrations (up to 43% for doping). In applications, vacancy-rich β-Li₃N variants demonstrate enhanced of 2.14 × 10⁻³ S cm⁻¹ at and thermodynamic stability against metal within a 0–0.48 V window, enabling stable cycling in all-solid-state metal batteries with critical current densities up to 45 mA cm⁻² and capacity retention over 5,000 cycles. It also supports with a capacity of up to 10.4 wt% H₂, positioning it as a model material for ion dynamics studies, though challenges like air sensitivity in humid conditions (stable only below 0.3% humidity for 150 hours) require controlled environments. Additionally, lithium nitride forms during lithium-mediated electrochemical synthesis and prelithiation processes for cathodes, enhancing efficiency and performance.

Overview

Chemical identity

Lithium nitride is an with the Li₃N. In this compound, adopts the +1 , while is in the -3 to form the anion. The compound is ionic in nature. Also known as trilithium nitride, its reflects the composition of three atoms bonded to one atom, with "" derived from and the suffix indicating an anionic species. The molecular weight is 34.83 g/mol. At , lithium nitride appears as a reddish-brown solid, often in powder or crystalline form.

Historical background

Lithium nitride was first synthesized in 1892 by L. Ouvrard, who heated metallic to dull redness in a stream of gas, observing the formation of a reddish-brown compound. Shortly thereafter, M. Guntz confirmed this preparation method and noted the compound's reactivity with water to produce . In the late , early studies observed lithium nitride's formation during the combustion of lithium metal in air, as lithium uniquely reacts with atmospheric among metals to yield the alongside . These observations highlighted its distinct chemical behavior compared to other elements, which do not form stable nitrides under similar conditions. The of lithium nitride was first determined in 1935 by E. Zintl and G. Brauer using diffraction on single crystals, revealing a hexagonal layered arrangement with P6/mmm. This structural insight provided a foundation for understanding its properties, later refined in subsequent analyses. A key milestone came in 1976 when U. von Alpen and colleagues identified lithium nitride as an exceptionally fast lithium-ion conductor, with conductivity on the order of 10^{-3} S/cm at , sparking interest in its potential for solid-state ionics.90082-7/abstract)

Physical and structural properties

Lithium nitride (Li_3N) exists primarily in its \alpha-phase at ambient conditions, characterized by a hexagonal in the P6/mmm (No. 191). This phase features a layered arrangement where N^{3-} ions form discrete, planar hexagonal lattices within Li_2N planes, separated by intercalated Li^{+} ions that occupy octahedral coordination sites between the layers. The structure contains two inequivalent Li^{+} sites: one coplanar with the N^{3-} ions in the hexagonal layers and the other positioned along the c-axis, linking adjacent layers. The structure includes inherent lithium vacancies of about 3% at , contributing to its ionic conductivity. The lattice parameters for \alpha-Li_3N are a = 3.648(1) and c = 3.875(1) , with four ions per . The bonding in \alpha-Li_3N is predominantly ionic, reflecting the large electronegativity difference between and , which stabilizes the N^{3-} anion. Under moderate pressure, \alpha-Li_3N transforms to the \beta-phase at approximately 0.5 GPa, adopting a hexagonal in the space group P6_3/mmc (No. 194). This polymorph consists of honeycomb-like LiN layers stacked in an ABAB sequence, with N^{3-} ions coordinated by six Li^{+} ions in a more compact arrangement than the \alpha-phase; the \beta-phase is metastable at but remains stable up to about 35 GPa. At higher pressures of 35–45 GPa, a first-order phase transition occurs to the \gamma-phase, which has a cubic structure in the Fm\bar{3}m (No. 225). In this dense polymorph, the N^{3-} ions retain their identity within a rock-salt-like , with Li^{+} ions distributed in octahedral and tetrahedral sites, and the phase persists with ionic bonding up to at least 200 GPa.

Key physical characteristics

Lithium nitride, specifically the alpha phase (α-Li₃N) stable at , exhibits a of 1.27 g/cm³. The compound does not melt but at approximately 850°C under ambient conditions. Its thermal properties include a of approximately 2.2 J/g·K at and stability up to 800°C in an inert atmosphere, beyond which decomposition to lithium and gas occurs. Optically, α-Li₃N is an indirect with a band gap of 2.1 , enabling potential applications in optoelectronic devices. Electrically, it demonstrates high ionic conductivity of approximately 10⁻³ S/cm at 300 K, primarily due to Li⁺ diffusion facilitated by vacancies in its layered structure. Regarding , lithium nitride is insoluble in most solvents but decomposes in .

Synthesis and handling

Preparation methods

Lithium nitride is primarily synthesized through the direct reaction of elemental with gas, following the equation $6 \mathrm{[Li](/page/Li)} + \mathrm{N_2} \rightarrow 2 \mathrm{Li_3N}. This process is conducted under a nitrogen atmosphere at temperatures typically ranging from to 500 °C, well above the of (180.5 °C), to facilitate the reaction with either solid or molten . Using molten promotes a more uniform and dense product formation due to increased surface area and reactivity. Alternative laboratory methods include dissolving in liquid sodium and reacting the solution with gas, enabling synthesis at lower temperatures and yielding single crystals of lithium nitride. The excess sodium is subsequently removed via . Another route involves the of lithium , described by $3 \mathrm{LiN_3} \rightarrow \mathrm{Li_3N} + 4 \mathrm{N_2}, which proceeds under nearly thermoneutral conditions. Electrochemical approaches entail the of lithium metal from a lithium salt , followed by its spontaneous reaction with to form the nitride. On an industrial scale, emphasizes atmospheric control to minimize from oxygen or moisture, achieving purities exceeding 99% through refined direct nitridation processes. Challenges include managing impurities like oxides, often addressed via inert handling and optimized reaction parameters. Purification of lithium nitride commonly employs sublimation to eliminate residual impurities, leveraging the compound's under reduced pressure to deposit a cleaner sublimate. This method results in the characteristic structure of the material.

Safety considerations

Lithium nitride is highly reactive and poses significant fire and explosion risks due to its pyrophoric nature in moist air, where the powder can ignite spontaneously and burn with intense heat. It also reacts violently with , producing gas and according to the equation \ce{Li3N + 3 H2O -> 3 LiOH + NH3}, which can lead to rapid gas evolution, potential ignition of the flammable or , and severe thermal hazards. This reactivity extends to acids, , and other substances, necessitating strict avoidance of moisture and oxidants during handling to prevent uncontrolled reactions. Exposure to lithium nitride presents notable toxicity concerns, primarily through and corrosive effects. Direct contact causes severe burns to , eyes, and mucous membranes, while inhalation of dust can result in respiratory , including symptoms such as coughing, wheezing, , and potential . The release of during reactions exacerbates respiratory risks, as is a toxic gas that can cause acute to the eyes, , and at concentrations above 25 ppm. Additionally, lithium ions from the compound may lead to systemic effects like , , or upon ingestion or prolonged exposure, though specific data for lithium nitride is limited. Proper storage of lithium nitride requires an inert atmosphere, such as or , in sealed, airtight containers to exclude moisture and oxygen, with recommendations to use amber glass or compatible materials at controlled temperatures. Handling should occur in a or under positive pressure , with including gloves, safety goggles, and respiratory protection against dust; all work surfaces must be dry and free of ignition sources. For disposal, lithium nitride must be neutralized under controlled conditions, typically by slow addition to a dilute acid solution (such as hydrochloric acid) in a well-ventilated fume hood to form soluble lithium salts and ammonium compounds, followed by pH adjustment and verification before wastewater discharge or solid waste disposal. Spills should be covered with dry lime, sand, or soda ash without using water, then collected for disposal as hazardous waste. It is classified under UN 2806 as a Class 4.3 dangerous good (flammable solid, dangerous when wet), requiring compliance with international transport regulations for Packing Group I materials. All disposal activities must adhere to local environmental regulations to prevent environmental release of lithium or ammonia.

Chemical reactivity

General reactivity

Lithium nitride exhibits notable stability in dry air at elevated temperatures, though it becomes reactive in moist environments due to its sensitivity to . At higher temperatures, it thermally above 815°C under , yielding metal and gas, with the exothermic of decomposition measured at -171.3 ± 7.7 kJ/mol at 298 . As an ionic compound featuring the nitride ion (N³⁻), lithium nitride behaves as a strong base, readily reacting with protic solvents such as to form and , often violently and exothermically. This basicity stems from the high of the N³⁻ ion, which facilitates proton abstraction in acidic or protic media. In terms of behavior, lithium nitride serves as a potent , attributable to the low of Li⁺ (approximately -3.04 V vs. SHE), enabling it to donate electrons in various systems, such as reductions involving complexes. It is incompatible with strong oxidizing agents, including oxygen and , where reactions can be vigorous or explosive, as seen with . Regarding compatibility, lithium nitride shows inertness toward most organic solvents, remaining largely insoluble and non-reactive in non-protic media like under controlled conditions. However, its reactivity with halogens and oxygen underscores the need for inert atmospheres during handling to prevent unwanted redox interactions.

Specific reactions

Lithium nitride undergoes hydrolysis with water at room temperature, producing lithium hydroxide and ammonia gas according to the reaction: \mathrm{Li_3N + 3 H_2O \rightarrow 3 LiOH + NH_3} This process is highly exothermic and proceeds violently due to the strong basicity of Li₃N, necessitating careful handling to avoid rapid gas evolution and heat release. Lithium nitride reacts with carbon dioxide to form lithium cyanamide (Li₂CN₂) and amorphous carbon nitride materials in an exothermic reaction initiated at approximately 330°C. Thermodynamic calculations confirm a spontaneous heat-releasing process that enables rapid conversion under controlled conditions. Hydrogenation of lithium nitride proceeds in a reversible two-step manner, beginning with the formation of lithium imide and : \mathrm{Li_3N + H_2 \rightleftharpoons Li_2NH + LiH} This initial step absorbs about 5.7 wt% and is typically conducted at around 200°C under moderate , with the exhibiting favorable reversibility for applications. The overall system can achieve up to 10.4 wt% capacity upon completing the second step (Li₂NH + H₂ ⇌ LiNH₂ + LiH) at higher temperatures near 270°C, highlighting its potential in solid-state . Lithium nitride reacts with various metals to form alloys or compounds, often yielding ternary nitrides. For instance, reactions with early transition metals like , , and produce phases such as Li₂CeN₂, Li₂ThN₂, and Li₂HfN₂ through sequential formation of mononitrides followed by ternary products. In battery contexts, combinations with magnesium, such as in Li-Mg-N systems, enable the development of structures suitable for cathodes, enhancing electrochemical performance in lithium-based cells.

Applications

Energy storage

Lithium nitride (Li₃N) is utilized as a solid in all-solid-state lithium-metal batteries owing to its high Li⁺ ionic of approximately $10^{-3} S/cm at , which facilitates efficient transport across the . This conductivity arises from the layered hexagonal structure of α-Li₃N, enabling two-dimensional Li⁺ diffusion with low . In these batteries, Li₃N interfaces effectively suppress lithium formation by promoting uniform Li plating and providing mechanical stability against volume changes during cycling, thereby enhancing safety and longevity. For instance, vacancy-rich β-Li₃N variants achieve conductivities up to $2.14 \times 10^{-3} S/cm while maintaining critical current densities exceeding 30 mA/cm² without penetration. As a cathode material or prelithiation additive, contributes to enhanced in lithium-sulfur (Li-S) and lithium-air (Li-air) batteries by serving as a source that compensates for initial capacity loss. In Li-S systems, incorporation of stabilized Li₃N into the boosts reversible capacity through efficient Li⁺ delivery, outperforming conventional additives by providing over 10 times the theoretical capacity of standard cathode hosts. Similarly, in Li-air configurations, Li₃N aids in stabilizing the cathode-electrolyte , mitigating side reactions with oxygen and improving overall utilization, though its primary role remains supportive rather than the active oxygen host. The reversible Li-N-H system, derived from , achieves a theoretical of up to 11.5 wt% H₂ through stepwise reactions involving () and () intermediates. This system operates via dehydrogenation at elevated temperatures, releasing H₂ from LiNH₂ + LiH to form , followed by further release to . Cycle stability reaches up to 500 cycles under pressure cycling conditions at 250–300°C, with minimal fade when using purified , demonstrating viability for practical storage applications despite challenges from byproduct formation. Advances in Li₃N-based from 2020 to 2025 emphasize nanostructured composites, such as α-Li₃N nanofibers, which lower Li⁺ energies to 0.05–0.08 and accelerate via enhanced vacancy-mediated hopping. These modifications enable faster charge-discharge rates and improved interfacial compatibility in solid-state electrolytes (SSEs). Integration of such Li₃N SSEs supports all-solid-state batteries targeting energy densities of 500 Wh/kg, with demonstrated pouch cells retaining over 90% capacity after thousands of cycles, as reviewed in recent RSC literature.

Other uses

Lithium nitride serves as a versatile in , particularly in the preparation of N,N-diacylamides through its reaction with acid chlorides. This process involves the direct amidation where lithium nitride reacts with acyl chlorides to form the corresponding diacylamides in good yields, offering a straightforward route to these compounds that are useful as intermediates in pharmaceutical and material . As a , lithium nitride finds application in the of low-valent metal complexes, notably in coordinating solvents where it liberates dinitrogen. For instance, it reduces (IV) chloride to lithium tetrachlorotitanate(IV) coordinated with , and it also facilitates the reduction of cyclopentadienyl chlorides to form (IV) and cluster complexes such as [(η⁵-C₅H₅)₂TiCl]₂ and (C₅H₅)₆Ti₆(C₅H₄)₂N. These reactions highlight its utility in for generating reactive species employed in and . In catalytic processes, lithium nitride acts as a key intermediate in direct nitrogenation reactions using dinitrogen as the nitrogen source. Generated in situ from metal and , it enables palladium-catalyzed C–N bond formation with aryl halides, leading to the synthesis of arylamines, biarylamines, triarylamines, and N-heterocycles such as carbazoles with yields up to 87%. This method provides an efficient, sustainable approach to nitrogen-containing organic molecules, bypassing traditional ammonia-based processes and supporting applications in and pharmaceuticals. Lithium nitride plays a crucial role in lithium-mediated electrochemical ammonia synthesis (LiMEAS), where its formation from dissociated at the surface is essential for selective production. Density functional theory studies show that appropriate proton donors enhance Li₃N stability by promoting surface reconstruction, increasing electron transfer to and improving overall efficiency. This application advances sustainable technologies, potentially reducing reliance on the energy-intensive Haber-Bosch process.