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Gold compounds

Gold compounds are chemical substances containing the element gold (Au), a noble transition metal renowned for its chemical inertness and resistance to most reagents, yet capable of forming a variety of coordination, organometallic, and ionic compounds primarily in the +1 (Au(I)) and +3 (Au(III)) oxidation states. These states dominate gold chemistry, with Au(I) typically exhibiting linear coordination geometries and diamagnetic properties, while Au(III) adopts square-planar arrangements and shows greater reactivity toward reduction. Common examples include halides such as auric chloride (AuCl₃), cyanides like the gold(I) complex [Au(CN)₂]⁻, oxides including gold(III) oxide (Au₂O₃) and hydroxide (Au(OH)₃), and sulfides. The formation of gold compounds often requires specific conditions, such as dissolution in —a mixture of one part and three parts —to produce chlorauric acid (HAuCl₄), which serves as a precursor for many derivatives. Gold's nobility stems from its high and reluctance to oxidize, but relativistic effects from its high enhance orbital interactions, stabilizing bonds in low-valent states and enabling unique reactivity in organogold species. Higher oxidation states like +4 are rare and typically observed in gas-phase or stabilized clusters, while anionic gold chemistry, such as Au⁻ species, highlights its versatility beyond cationic forms. Gold compounds have significant applications across multiple fields, including homogeneous and for —such as activations and heterocycle formations—and for nanowires and conductive polymers. In , gold(I) thiolates like auranofin are used in chrysotherapy to treat by modulating immune responses. and also rely on gold alloys and coatings for their resistance and , while environmental impacts remain low due to gold's insolubility and minimal . Recent advancements since the early have revitalized interest in gold(III) catalysis and bimetallic clusters, expanding their role in sustainable chemistry.

General properties

Physical characteristics

Gold compounds frequently display vibrant colors arising from electronic transitions involving the d-band, which influence light absorption and reflection in the visible spectrum. Compounds in the +1 oxidation state, such as gold(I) chloride (AuCl), are typically yellow solids. In contrast, those in the +3 oxidation state, exemplified by gold(III) chloride (AuCl₃), appear as yellow to dark red crystalline materials. Solubility patterns among gold compounds vary with oxidation state and counterions. Most gold(I) halides, including AuCl, are insoluble or only slightly soluble in water but dissolve in aqua regia, a mixture of nitric and hydrochloric acids that facilitates oxidation and complexation. Gold(III) chloride, however, exhibits high solubility in water, where it readily forms the tetrachloroaurate ion (HAuCl₄) in acidic conditions, with solubility reaching approximately 680 g/L at 20°C. Crystal structures of gold compounds reflect the preferred coordination geometries dictated by the . (I) species often adopt linear coordination, as seen in gold(I) cyanide (AuCN), which forms infinite chains of linear Au–C–N–Au units in a arrangement. (III) complexes, conversely, favor square planar geometry, characteristic of d⁸ configuration, such as in the tetrachloroaurate anion (AuCl₄⁻), where the center is surrounded by four chloride ligands in a planar array. Many gold compounds possess higher densities compared to their silver analogs, attributable to gold's greater . For instance, AuCl has a density of 7.6 g/cm³, exceeding that of (AgCl) at 5.56 g/cm³. Regarding thermal stability, AuCl₃ (often handled as its hydrated form) melts at 254°C and decomposes above 290°C, releasing and forming lower valent gold species. wait no, avoid wiki; use for AgCl density or standard. Wait, for citations, use proper. Actually, for AgCl, cite PubChem or something. For AuCl density, from earlier 7.57.

Chemical reactivity

Gold compounds exhibit notable chemical inertness, primarily attributed to relativistic effects that stabilize the 6s electrons of gold, resulting in high ionization energies that hinder oxidation and reactivity. The first ionization energy of gold is 890.1 kJ/mol, and the second is 1980.3 kJ/mol, values elevated by these relativistic contractions of the 6s orbital, which increase the effective nuclear charge and make electron removal more energetically demanding. This nobility renders most gold compounds resistant to oxidation in air at ambient conditions, though they can decompose thermally; for instance, gold(III) oxide (Au₂O₃) decomposes to metallic gold and oxygen above approximately 150°C. Despite this stability, gold compounds display specific reactivity patterns, particularly in solution. Gold(I) species in aqueous media tend to disproportionate according to the equilibrium 3Au⁺ → 2Au + Au³⁺, driven by the instability of the +1 relative to elemental and the +3 state, with this process observable even at 25°C for complexes. Conversely, gold(III) compounds are sensitive to reducing agents, readily undergoing reduction to gold(0) or gold(I); thiols efficiently reduce Au(III) to Au(I) thiolates, forming stable intermediates, while ascorbate reduces Au(III) complexes in acidic solutions. In terms of coordination chemistry, gold compounds favor distinct geometries that influence their reactivity: gold(I) typically adopts linear, two-coordinate structures due to the d¹⁰ configuration and relativistic effects promoting sp hybridization, whereas gold(III) prefers square planar, four-coordinate arrangements, consistent with d⁸ electron counts and ligand field stabilization. These preferences contribute to the overall reluctance of gold compounds to engage in substitution or redox reactions under mild conditions, underscoring their utility in specialized applications.

Oxidation states

+1 oxidation state

in the +1 , denoted as Au(I), exhibits a d¹⁰ , rendering it diamagnetic due to the absence of unpaired electrons. This closed-shell structure contributes to its high , particularly in two-coordinate linear geometries, which minimize steric repulsion and maximize orbital overlap. According to the hard-soft -base (, Au(I) acts as a soft , preferentially forming stable complexes with soft ligands such as phosphines, thioethers, and cyanides, which enhance its thermodynamic through favorable polarizable interactions. Representative compounds of Au(I) include gold(I) chloride (AuCl), a yellow solid that is highly unstable and decomposes readily to metallic gold and gold(III) chloride. Another key example is gold(I) cyanide (AuCN), an insoluble white precipitate in water, widely employed in electroplating processes due to its ability to form soluble complexes in alkaline cyanide solutions for controlled gold deposition. The of Au(I) compounds like AuCl is exemplified by their tendency to undergo , as seen in the $3 \mathrm{AuCl_2^-} \rightleftharpoons \mathrm{AuCl_4^-} + 2 \mathrm{Au(s)} + 2 \mathrm{Cl^-} which strongly favors the products at 25°C with an derived from log K = −13.55 + 8593/T − 700610/T² (where T is in ), yielding a large K value indicative of rapid decomposition under ambient conditions. This highlights the relative instability of mononuclear Au(I) halides in aqueous media, often catalyzed by metallic gold surfaces. Spectroscopically, Au(I) complexes typically display weak ligand-to-metal charge transfer (LMCT) bands in the region around 300 , arising from transitions involving soft ligand donors to the empty antibonding orbitals of the linear Au(I) center; for instance, peaks near 295 have been observed in phosphine-supported derivatives. These absorptions are generally low-intensity due to the forbidden nature of the transitions in the d¹⁰ configuration.

+3 oxidation state

Gold(III) exhibits a d⁸ electronic configuration, which favors a square planar in its coordination complexes due to the low-spin arrangement of electrons in the d orbitals. This configuration contributes to the stability of four-coordinate species and influences the compound's reactivity, particularly in catalytic applications. The Au(III)/Au(I) couple has a standard potential of +1.41 V, underscoring its potent oxidizing nature and tendency toward reduction under mild conditions. Synthesis of gold(III) compounds typically involves the dissolution of metallic in , a mixture of concentrated nitric and hydrochloric acids that oxidizes Au(0) to Au(III) while forming stable chloro complexes. The balanced reaction is: \mathrm{Au + 3 HNO_3 + 4 HCl \rightarrow HAuCl_4 + 3 NO_2 + 3 H_2O} This process yields (HAuCl₄), a key precursor for other Au(III) species, and proceeds via initial oxidation by followed by complexation with chloride ions. Prominent gold(III) compounds include gold(III) chloride (AuCl₃), a hygroscopic, light-sensitive solid that exists as a dimer (Au₂Cl₆) in the solid state, featuring bridging chloride ligands. Another example is gold(III) oxide (Au₂O₃), a brown powder that decomposes thermally to elemental gold and oxygen above 160 °C, reflecting the instability of higher oxidation states in oxide form. In aqueous media, Au(III) readily forms the stable tetrachloroaurate ion ([AuCl₄]⁻), which is square planar and serves as a versatile intermediate. The Au–Cl bond length in AuCl₃ is approximately 2.28 Å, shorter than in lower oxidation states due to increased effective nuclear charge and relativistic contraction effects. The reactivity of gold(III) is dominated by its strong oxidizing character; for instance, AuCl₃ is readily reduced by (CO) to metallic gold (Au(0)), often forming colloidal particles in the process. This reduction highlights the thermodynamic drive toward lower oxidation states, with [AuCl₄]⁻ similarly susceptible to reductants, enabling applications in synthesis and .

Binary compounds

Gold halides

Gold halides are binary compounds formed between gold and the chlorine, , and iodine, primarily in the +1 and +3 oxidation states. These compounds exhibit distinct structural motifs influenced by the relativistic effects of , leading to linear coordination in Au(I) species and square-planar geometry in Au(III) species. Synthesis typically involves direct reaction of metal with under controlled conditions, while their properties reflect the nobility of , with varying thermal stability and reactivity as Lewis acids or in catalytic applications. Gold fluorides are less common due to gold's lower affinity for . AuF₃, a red solid, is synthesized by fluorination of AuCl₃ and features a polymeric structure with bridging around square-planar Au(III) centers. The Au(I) , AuCl, AuBr, and AuI, are yellow to pale yellow crystalline solids that adopt polymeric chain structures in the solid state, featuring linear Au-X-Au bridges where the ions act as unsupported bridges between gold centers, resulting in zig-zag chains with Au-X-Au angles less than 180°. These structures arise from the d^{10} of Au(I), promoting aurophilic interactions and linear two-coordinate geometry. Among them, AuI is the most thermally stable, decomposing only at higher temperatures compared to AuCl and AuBr, which disproportionate more readily to Au(0) and Au(III). Synthesis of these monohalides often proceeds via reduction of Au(III) precursors or direct combination, such as reacting gold powder with iodine vapor. In contrast, the Au(III) halides AuCl₃, AuBr₃, and AuI₃ are more reactive and less stable, with AuCl₃ appearing as red-brown crystals that are highly volatile. These trihalides typically exist as dimers in the solid state, such as Au₂Cl₆, featuring two bridging halides and square-planar coordination around each Au(III) center, consistent with its d⁸ configuration. AuBr₃ is dark red and similarly dimeric, while AuI₃ is black and decomposes easily to AuI and I₂, reflecting decreasing stability down the halogen group due to weaker Au-I bonds. In solution, Au(III) halides readily form tetrahedral [AuX₄]⁻ anions upon addition of excess halide ions, as seen in from . A representative is the direct chlorination of at elevated temperatures: 2Au + 3Cl₂ → 2AuCl₃, typically conducted by passing Cl₂ over gold powder at around 180°C. Unique properties of gold halides include their catalytic utility and mixed-valence behavior. AuCl₃ serves as an effective Lewis acid catalyst for hydration, promoting the addition of across the triple bond to form ketones under mild conditions, often outperforming traditional (II) catalysts due to its milder acidity. Iodide derivatives exhibit interesting mixed-valence chemistry, such as Au₂I₃, which contains both Au(I) and Au(III) centers linked by bridges, displaying electronic delocalization akin to other aurous-auric systems. Regarding thermal stability, AuCl₃ begins to decompose at approximately 180°C, releasing and forming AuCl, which contributes to the volatility of gold halides in vapor-phase applications compared to gold oxides, which decompose without subliming; this volatility facilitates their use in vapor-phase applications but limits handling at high temperatures. Au(III) halides generally act as strong oxidants, with reactivity decreasing from to .

Gold oxides and chalcogenides

Gold oxides are limited in number and generally exhibit low stability due to 's preference for lower oxidation states and relativistic effects that weaken Au-O bonds. The (I) oxide, Au₂O, appears as a black solid and is highly unstable, existing only as a metastable that decomposes or disproportionates into metallic and higher oxides under ambient conditions. Au₂O is endothermic with a positive of formation of +0.228 , rendering it prone to rapid above 150°C into and oxygen. In contrast, gold(III) oxide, Au₂O₃, is the most stable gold oxide, forming a red-brown solid that is amphoteric, readily dissolving in strong acids to form auric salts or in bases to yield gold(III) hydroxo complexes. Au₂O₃ is a semiconductor with a band gap of approximately 0.85 eV and can be synthesized by alkaline precipitation of HAuCl₄ solutions, yielding hydrated Au(OH)₃ that dehydrates upon gentle heating to the oxide. It decomposes thermally at 150–300 °C depending on hydration and conditions, via the reaction $2\mathrm{Au_2O_3} \rightarrow 4\mathrm{Au} + 3\mathrm{O_2}, releasing oxygen and leaving metallic gold residue. Gold chalcogenides, encompassing compounds with , , and , are notable for their occurrence in natural ores and relative instability compared to other binary gold compounds, often displaying semiconducting properties and a tendency toward . Gold(I) , Au₂S, is a black, with extreme insolubility in (K_{sp} = 1.58 \times 10^{-73}). It forms accessory phases in some hydrothermal gold deposits, though pure binary Au₂S is rare in nature. Gold(I) , Au₂Se, is similarly dark and insoluble, with a polymeric structure featuring linear Au-Se coordination. Gold tellurides are particularly significant in , with (AuTe₂) serving as a key that contributes to placer deposits through , releasing native particles. Au₂Te₃, a related , occurs in synthetic and minor natural forms but is less common. These tellurides are processed industrially by to decompose the structure, oxidizing to TeO₂ and liberating for cyanidation. Tellurides dominate ores, often comprising up to 23% of concentrates in deposits like those at . Chalcogenides generally display semiconducting behavior, particularly the sulfides, where two-dimensional Au₂S monolayers exhibit direct band gaps of 1.0–3.6 and high suitable for optoelectronic applications. The Au-S bonds in these compounds have a dissociation energy of approximately 254 kJ/mol, weaker than the Au-Cl bond at 280 kJ/mol, which contributes to their proneness to reductive and explains the challenges in extracting gold from ores without prior oxidation.

Coordination and complex compounds

Gold(I) complexes

Gold(I) complexes typically adopt linear, two-coordinate geometries due to the d¹⁰ electronic configuration of Au(I), which favors coordination with soft ligands such as phosphines, thiols, and cyanides according to the hard-soft acid-base (HSAB) theory. These complexes are prevalent in coordination chemistry and have applications in medicine and materials science. A representative example is chlorido(triphenylphosphine)gold(I), [Au(PPh₃)Cl], which features a nearly linear P-Au-Cl bond angle of approximately 180° and is structurally analogous to the active component in the antirheumatic drug Auranofin, where triethylphosphine replaces triphenylphosphine and a thio sugar ligand is incorporated. Another common ligand set involves cyanide, forming the stable dicyanidoaurate(I) anion, [Au(CN)₂]⁻, which is linear and widely used in gold extraction processes. The bonding in gold(I) complexes is significantly influenced by relativistic effects, which contract the 6s orbital and expand the 5d orbitals of gold, enhancing Au-ligand interactions and contributing to the stability of these species with soft donors. A distinctive feature is aurophilicity, a closed-shell attraction between Au(I) centers resembling hydrogen bonding, with Au···Au distances around 3.0 Å in dimeric or polymeric structures; for instance, [Au(CN)₂]⁻ forms stacked arrays with short Au···Au contacts of 3.18–3.35 Å, stabilizing extended solids. Synthesis commonly proceeds via ligand exchange reactions, such as treating gold(I) chloride (AuCl) with the desired ligand in an inert atmosphere, yielding high-purity complexes; these exhibit high stability constants with soft bases, exemplified by log β₂ ≈ 38.3 for [Au(CN)₂]⁻ in aqueous solution. Thiosulfate ligands form [Au(S₂O₃)₂]³⁻, a robust complex with log β₂ ≈ 24, utilized in alternative gold leaching media. Spectroscopically, many gold(I) complexes display arising from metal-centered (³MMLCT) or ligand-to-metal charge-transfer transitions modulated by aurophilic interactions, often emitting in the green region around 500 nm; for example, polymeric [Au(CN)₂]⁻ salts show emissions at 430–500 nm depending on the Au···Au separation. This photophysical behavior underscores the role of Au···Au coupling in tuning for potential applications.

Gold(III) complexes

Gold(III) adopts a +3 in its coordination complexes, which are predominantly square planar due to the d⁸ electronic configuration, enabling a range of applications in and . These complexes typically feature soft ligands that stabilize the high oxidation state, with halides being the most common, followed by nitrogen donors such as (en) and oxygen donors like acetylacetonate, though the latter are less prevalent owing to inherent instability. Nitrogen-donor complexes, exemplified by [Au(en)₂]³⁺, exhibit sufficient stability under physiological conditions. Prominent examples include the tetrachloroaurate anion [AuCl₄]⁻, a widely used in gold etching processes due to its strong oxidizing nature in acidic media. In contrast, the fluoride analog [AuF₄]⁻ is rarer, requiring specialized conditions for isolation and often stabilized by counterions or additional ligands to prevent decomposition. These complexes serve as precursors for more elaborate structures, highlighting the versatility of Au(III) in coordination environments. Bonding in Au(III) complexes is characterized by a strong trans influence, where ligands like weaken the trans to them, resulting in typical Au–Cl distances of approximately 2.27 Å. Jahn–Teller distortion is minimal in these square-planar systems, preserving high and facilitating predictable substitution patterns. is a key challenge; Au(III) complexes hydrolyze readily in aqueous solutions to form Au(OH)₃, but chelating ligands such as acetylacetonate provide enhanced kinetic stability by preventing ligand dissociation and reduction. Reactivity of Au(III) complexes underscores their role as oxidants and catalysts; for instance, [AuCl₄]⁻ undergoes reduction with various reductants to yield Au(0) nanoparticles, a process exploited in synthesis. In catalysis, these species promote reactions like olefin through activation of C=C bonds via electrophilic coordination, often in cycles involving Au(I)/Au(III).

Organogold compounds

Carbon-gold bonds

Organogold compounds with direct carbon-gold bonds, known as organogold species, exist predominantly in the +1 and +3 oxidation states. Au(I) derivatives are typically two-coordinate and linear, as exemplified by the alkyl complex (Me₃P)AuMe, where the phosphine ligand and methyl group adopt a collinear P-Au-C geometry. In contrast, Au(III) organometallics are usually four-coordinate and square-planar, though five-coordinate intermediates can form during synthetic or reactive processes. Alkyl, aryl, and alkynyl groups serve as common carbon-based ligands, with aryl and alkynyl derivatives often showing enhanced stability compared to simple alkyls due to electronic and steric factors. These compounds are commonly synthesized through reactions, where a precursor reacts with an organometallic . A representative example is the treatment of chlorotriphenylphosphinegold(I) with an alkyllithium or : AuCl(PPh₃) + RLi → AuR(PPh₃) + LiCl, yielding stable Au(I) alkyl or aryl complexes. Similar strategies apply to Au(III) species, often starting from Au(III) salts and organolithium compounds, though yields can be lower due to competing reduction pathways. The stability of these C-Au bonds follows the trend alkynyl > aryl > alkyl, attributed to the stronger σ-donor ability and reduced reactivity of sp-hybridized carbon atoms in alkynyl groups, which minimize pathways like . The carbon-gold bond is primarily a σ-bond formed by donation from a carbon-based orbital to the gold d-hybrid orbital, with typical Au-C distances ranging from 2.00 to 2.10 Å in both Au(I) and Au(III) complexes, as determined by . Au(I) organometallics exhibit greater overall stability than Au(III) analogs, owing to the lower tendency for the d¹⁰ Au(I) center to undergo oxidation or elimination reactions. However, alkyl-substituted compounds are prone to decomposition via β-hydride elimination, particularly in Au(I) and Au(III) ethyl derivatives: Au-CH₂CH₃ → Au-H + CH₂=CH₂, which proceeds through a four-center and is facilitated by the presence of β-hydrogens. The historical development of organogold chemistry began with early Au(III) alkyls, such as trimethylgold prepared by Gilman in 1948 via reaction of AuBr₃ with MeLi. The first stable phosphine-supported Au(I) organogold compound, AuMe(PPh₃), was reported by Joseph Chatt and Luigi M. Venanzi in 1957, synthesized by of ClAu(PPh₃) with MeLi; this milestone enabled the isolation of monomeric, air-stable species and laid the foundation for modern organogold research.

Applications in synthesis

Organogold compounds, particularly Au(I) alkynyl complexes, play a significant role in catalytic processes, enabling efficient cycloisomerization of enynes through π-activation of the moiety without involving changes at the gold center. This mechanism proceeds via coordination of the electrophilic Au(I) to the triple bond, facilitating nucleophilic attack by the , which leads to the formation of cyclized products such as five- or six-membered rings with high regio- and . Seminal work by Echavarren and coworkers demonstrated that catalysts like (PPh₃)AuNTf₂ effectively promote these transformations under mild conditions, making them valuable for synthesizing complex carbocycles in natural product synthesis. Recent developments as of 2023 include the use of Au(I)/Au(III) in C-H bond functionalizations and asymmetric transformations, expanding the synthetic utility of organogold species.