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2-Aminophenol

2-Aminophenol, also known as o-aminophenol, is an with the molecular formula C₆H₇NO and a molecular weight of 109.13 g/mol. It features a ring with an amino (-NH₂) group and a hydroxyl (-OH) group attached in positions, rendering it amphoteric and capable of acting as a . This compound appears as white to light brown crystalline needles or powder that darkens to tan or brown upon exposure to air and light due to oxidation. It has a melting point of 172 °C, sublimes at 153 °C at 11 mmHg, and a of 1.328 g/cm³. 2-Aminophenol exhibits limited in (17 g/L at 20 °C) but is readily soluble in and other polar solvents, while being insoluble in . Industrially, 2-aminophenol serves as a key intermediate in the synthesis of various heterocyclic compounds, including benzoxazoles, phenoxazines, and oxyquinolines, which find applications in pharmaceuticals and . It is also widely used in the production of dyes, particularly azo dyes, and as a component in colorants to achieve diverse shades. The compound is typically synthesized by the reduction of o-nitrophenol using agents such as or catalytic . Regarding safety, 2-aminophenol is classified as or inhaled, with an oral LD50 of 951 mg/kg in rats, and is suspected of causing genetic defects (mutagenicity category 2). It can cause sensitization, , and respiratory issues like upon exposure, necessitating handling under fume hoods with appropriate such as gloves and .

Chemical Identity and Properties

Molecular Structure

2-Aminophenol has the C₆H₇NO and a molecular weight of 109.13 g/mol. Its IUPAC name is 2-aminophenol, with common synonyms including o-aminophenol and 2-hydroxyaniline. The molecule consists of a benzene ring with ortho-substituted amino (-NH₂) and hydroxyl (-OH) groups, giving it the structure where the -NH₂ is attached at position 2 relative to the -OH at position 1. The close proximity of the -NH₂ and -OH groups enables strong intramolecular hydrogen bonding, typically of the type N-H···O, which maintains the molecule in a planar conformation and enhances its thermal stability compared to non-hydrogen-bonded isomers. This bonding favors the cis conformer, where the OH group is oriented toward the NH₂, as determined by calculations showing an energy difference of approximately 1.7 kcal/mol relative to the conformer. 2-Aminophenol undergoes amino-imino , equilibrating with 2-iminophenol, a structure featuring an imino (=NH) group and a monimine (cyclohexa-2,5-dien-1-one with =NH at position 2) form, though the amino tautomer predominates due to aromatic stabilization. The lies heavily toward the amino-phenol form, with the imino tautomer being less stable by several kcal/mol. Spectroscopic methods confirm the structural features of 2-aminophenol. In the (IR) spectrum, the N-H and O-H stretching vibrations appear as broad bands in the 3200–3500 cm⁻¹ region, shifted and broadened due to the intramolecular hydrogen bonding. The ¹H NMR spectrum in DMSO-d₆ shows aromatic proton signals at approximately 6.40, 6.54, 6.59, and 6.65 , reflecting the deshielding effects from the substituents, with the NH₂ protons appearing around 4.4 . The structural arrangement can be represented as follows, where the benzene ring is substituted at positions 1 (OH) and 2 (NH₂): 
  OH
   |
  / \
 /   \
|     |  NH₂
 \   /
  \ /
   |
For the imino (2-iminophenol), the structure involves migration of the from nitrogen to oxygen, resulting in a =NH and C=O, disrupting in the ring to form the monimine: 
  O
   ||
  / \
 /   \
|     |  =NH
 \   /
  \ /
   |
This tautomerism influences reactivity but is minor in the .

Physical Properties

2-Aminophenol is typically observed as an off-white to light tan crystalline solid, often appearing as colorless needles or white powder that turns tan to brown upon exposure to air or light. It possesses a faint amine-like odor. The compound exhibits a melting point of 170–175 °C (lit.). It does not have a well-defined boiling point at atmospheric pressure, instead decomposing upon heating above approximately 220–235 °C. Its density is 1.33 g/cm³ at 25 °C. Regarding solubility, 2-aminophenol is sparingly soluble in , with a solubility of 1.7 g/100 mL at 20 °C, though it dissolves more readily in hot . It shows good solubility in polar organic solvents such as alcohols and ethers. The pKa values are 4.78 for the conjugate of the amino group and 9.97 for the hydroxyl group at 20 °C, reflecting its amphoteric character. 2-Aminophenol is sensitive to oxidation by air, which causes discoloration to brown, and it is recommended to store it in an inert atmosphere away from light to maintain stability.

Chemical Properties

2-Aminophenol exhibits amphoteric behavior due to the presence of both a phenolic hydroxyl group, which imparts weak acidic properties, and an amino group, which confers weak basic properties akin to aniline. The pKa value for the conjugate acid of the amino group is 4.78, reflecting its protonation equilibrium in acidic media, while the pKa for the phenolic OH deprotonation is 9.97 at 20 °C, indicating acidity in basic conditions. The basic character generally predominates in neutral aqueous solutions, allowing it to form salts with strong acids. The compound is susceptible to oxidation, readily forming o-quinone imine intermediates upon exposure to atmospheric oxygen or chemical oxidants, which can lead to further coupling reactions yielding phenoxazinone derivatives. This reactivity is exploited in qualitative tests, where treatment with ferric chloride (FeCl₃) produces a characteristic cherry red colored complex. In reactions, the strongly activating /para-directing effects of both the amino (-NH₂) and hydroxy (-) groups favor attack at positions 4 and 6 relative to the amino group, enhancing reactivity at these sites due to stabilization of the complex. This dual activation makes the ring highly electron-rich, promoting substitutions like or preferentially at the para position to the amino group when the hydroxyl is protected or under controlled conditions. 2-Aminophenol acts as a bidentate in coordination , forming stable chelate complexes with divalent and trivalent metal ions through its and oxygen donor atoms, which coordinate via the amino and groups after . These complexes, such as those with Cu(II), Ni(II), or Fe(III), exhibit enhanced stability due to five- or six-membered ring formation, and they are studied for applications in and bioinorganic modeling. Upon heating, 2-aminophenol undergoes above 220 °C, releasing toxic nitrogen oxides (NOₓ) and fragmenting into smaller molecules, including and phenolic residues, consistent with the behavior of aromatic amines and . This process involves initial or bond cleavage, leading to volatile products and char formation in inert atmospheres.

Synthesis

Industrial Methods

The primary industrial method for producing 2-aminophenol involves the of 2-nitrophenol, which is achieved either through the classical iron/HCl process or modern catalytic using (Pd/C) with gas. In the iron , 2-nitrophenol is treated with iron powder in acidic conditions, typically at temperatures of 80–100 °C, yielding over 90% after accounting for byproducts like iron . Catalytic , the preferred contemporary approach, operates under similar temperatures (80–100 °C) and moderate pressures (around 30 bar), achieving yields exceeding 95% with Pd/C catalysts in aqueous or alcoholic media, offering higher efficiency and reduced waste compared to metal reductions. During the , production shifted from batch iron reductions to continuous catalytic processes, enhancing scalability, yield consistency, and environmental compliance in large-scale facilities. Global production of 2-aminophenol reaches several thousand tons annually, primarily driven by demand in the dye industry, with major producers concentrated in and , where companies like Dehao Technology maintain capacities of up to 6,000 tons per year. Post-reduction, the crude product undergoes purification via to remove volatile impurities, followed by recrystallization from water or aqueous solvents, attaining purity levels above 98% for technical-grade material.

Laboratory Preparation

One common laboratory method for preparing 2-aminophenol involves the of 2-nitrophenol using tin and (Sn/HCl). In a typical procedure, 2-nitrophenol is dissolved in or a of ethanol and water to form a solution, typically at concentrations of 0.1–0.5 M for small-scale reactions (1–10 g starting material). Granular tin is then added portionwise, followed by concentrated , with the refluxed for 2–3 hours under stirring to facilitate the of the nitro group to . The progress is monitored by using plates with / (9:1) as eluent, where 2-nitrophenol (Rf ≈ 0.6) converts to 2-aminophenol (Rf ≈ 0.3). After cooling, the is basified with solution (10–20%) to pH 8–10 to liberate the free base, and the product is extracted with or (3 × 50 mL). The organic layers are combined, dried over anhydrous , and evaporated under reduced pressure to yield crude 2-aminophenol, which is further purified by recrystallization from hot water or , affording colorless needles. Small-scale yields typically range from 70–80%, with common impurities including unreacted 2-nitrophenol and trace amounts of the isomer arising from minor isomerization or starting material contamination. An alternative reduction employs (Na2S) as the reductant, particularly useful for aqueous conditions to avoid solvents. The procedure begins by dissolving 2-nitrophenol in hot (approximately 1.5–2.5 L per 300 g, adjusted for scale), followed by slow addition of aqueous Na2S·9H2O (1.5–2 equivalents) over 1–2 hours while maintaining the temperature at 80–90°C using a or . The mixture is then heated for an additional 15–30 minutes, filtered hot to remove residues, and acidified with dilute HCl to 4–5 to precipitate the product. The solid is collected by filtration, washed with cold , and recrystallized from boiling to obtain pure 2-aminophenol. Yields in this method are generally 75–85% on a scale, with similar impurities to the Sn/HCl route, such as the isomer. Purity is verified by HPLC using a C18 column with a / (40:60) mobile phase at 254 nm detection, targeting >95% for the main peak at retention time ≈5 min. Another route involves diazotization of followed by , though this approach faces challenges due to the mixture of - and para-substituted products from steps preceding diazotization. is first nitrated to a mixture of o- and p-nitroanilines, separated by or ; the o-nitroaniline fraction is then diazotized with NaNO2/HCl at 0–5°C and hydrolyzed by to yield o-nitrophenol, which is subsequently reduced as described above. This multi-step process achieves overall yields of 60–70% but requires careful separation to minimize para-isomer contamination. Laboratory safety considerations include working in a due to HCl fumes and potential H2S evolution in the Na2S method; tin-containing waste from the Sn/HCl procedure must be collected separately as it is hazardous and requires proper disposal per environmental regulations, avoiding direct contact with skin or inhalation of dust.

Applications and Reactions

Dye and Pigment Production

2-Aminophenol serves as a key intermediate in the synthesis of through diazotization followed by coupling reactions with phenolic or naphtholic compounds, yielding metal-complex dyes suitable for and applications. For instance, diazotized 2-aminophenol can undergo oxidative coupling in the presence of catalysts to form 2,2′-dihydroxyazobenzene, a representative with potential for further derivatization into colored products. These processes leverage the positioning of the amino and hydroxyl groups, facilitating stable chromophores that exhibit vibrant hues and good fastness properties. In the cosmetics industry, 2-aminophenol functions as a coupler in oxidative hair dyeing formulations where permitted by regulations, reacting with primary intermediates such as p-phenylenediamine under oxidation to produce indamine and derivatives responsible for brown and black shades. Its use is banned in since August 2023 due to concerns, and restricted in the to a maximum concentration of 2% in oxidative hair colorants (or 1% when combined with ). This reaction generates leuco intermediates that polymerize within the hair shaft, ensuring durable color with minimal fading. 2-Aminophenol is also employed in the production of heterocyclic pigments, particularly through cyclocondensation with aldehydes or carboxylic acids to form benzoxazole derivatives, which serve as fluorescent brighteners and optical whitening agents for synthetic fibers like . These benzoxazoles exhibit strong blue-violet , enhancing fabric whiteness under daylight. Similar cyclization strategies extend to analogs, though typically involving sulfur-containing variants, contributing to high-performance pigments in inks and coatings. The applications of 2-aminophenol in dyes trace back to the late , amid the rapid expansion of the synthetic sector led by German chemical firms such as , which pioneered industrial-scale production of azo and related colorants from aromatic amines. Today, the compound's consumption in the global and sector is estimated at approximately 10,000 tons annually, underscoring its ongoing industrial significance.

Pharmaceutical and Other Uses

2-Aminophenol serves as a key in the of heterocyclic compounds with pharmaceutical potential, including benzoxazole that exhibit and antibacterial activities. For instance, 2-aminobenzoxazole analogs derived from 2-aminophenol have demonstrated efficacy against crop pathogens in and assays, highlighting its role in developing novel therapeutic agents. Schiff bases formed by condensation of 2-aminophenol with substituted benzaldehydes also show promising antibacterial properties, attributed to their ability to inhibit through metal complexation or direct with microbial enzymes. Beyond pharmaceuticals, 2-aminophenol is utilized in the production of rubber antioxidants, where its reducing properties help prevent oxidative degradation during and extend material lifespan. Aminophenols like 2-aminophenol are incorporated into rubber formulations to inhibit free radical formation, improving thermal stability and mechanical performance in applications such as tires and . In , 2-aminophenol functions as a in developers for black-and-white film processing, facilitating the conversion of exposed silver halides to metallic silver while minimizing fogging. Its strong reducing capability, stemming from the ortho-positioned amino and hydroxyl groups, enables fine-grain with controlled . 2-Aminophenol plays a minor role in agrochemicals as a precursor for fungicides, herbicides, and insecticides. It is employed in the synthesis of oxazoline-based herbicides and insecticides, contributing to in crops like and . Derivatives such as 2-amino-4-nitrophenol have exhibited direct fungicidal effects against plant pathogens in laboratory tests. Emerging research since 2010 has explored 2-aminophenol as a for electrically conductive polymers in . Electropolymerized poly(2-aminophenol) films exhibit electrochemical stability and are investigated for applications in sensors, supercapacitors, and due to their redox-active properties and adhesion to substrates like or carbon electrodes.

Safety and Toxicology

Health Hazards

2-Aminophenol is acutely toxic following oral , with an LD50 value of 951 mg/kg in rats. This toxicity primarily manifests as , a condition where the compound oxidizes in red blood cells, reducing its oxygen-carrying capacity and potentially leading to symptoms such as , , and . Under EU CLP regulations, 2-aminophenol is classified as Acute Tox. 4 (H302: ), Skin Irrit. 2 (H315: Causes skin ), Eye Irrit. 2 (H319: Causes serious eye ), STOT SE 3 (H335: May cause respiratory ), and Muta. 2 (H341: Suspected of causing genetic defects). Chronic exposure to 2-aminophenol can result in skin sensitization, leading to upon repeated dermal contact. Dust or vapors from the compound may also cause eye , characterized by redness, tearing, and discomfort. Available data indicate limited evidence of carcinogenicity, with no classification by major regulatory bodies based on inadequate human and animal studies. The primary routes of exposure are and dermal . No specific (TLV) or OSHA (PEL) has been established for 2-aminophenol; exposure should be minimized to the lowest feasible level using and . Dermal exposure facilitates through the skin, exacerbating risks of and systemic . Upon , 2-aminophenol is rapidly metabolized, primarily through conjugation with or at the phenolic hydroxyl group, followed by excretion in . A portion may undergo oxidation to form reactive , such as o-quinone imine intermediates, which contribute to its toxic effects including formation. Safe handling requires (PPE), such as chemical-resistant gloves, safety goggles, protective clothing, and respiratory protection in poorly ventilated areas or when exposure may be significant. As of November 2025, no major updates to these health hazard assessments have been reported.

Environmental Impact

2-Aminophenol exhibits moderate biodegradability in aquatic environments, with screening tests demonstrating up to 95% degradation based on within 5 days using acclimated inoculum at concentrations of 100–200 mg/L. However, its can vary depending on environmental conditions, and it is expected to undergo primary processes in , though specific data in natural systems remain limited. The compound poses significant toxicity to aquatic organisms, with an LC50 of 0.1 mg/L reported for (Leuciscus idus) in acute exposure tests, indicating high sensitivity in freshwater ecosystems. Its low potential, characterized by a log Kow value of 0.62, suggests limited uptake in fatty tissues of organisms, but in dye industry effluents, 2-aminophenol can form colored complexes that exacerbate and hinder light penetration in water bodies. In the dye manufacturing sector, release presents challenges for due to its recalcitrance under conventional biological processes, often requiring advanced methods such as adsorption onto pretreated biochars or oxidative degradation using membrane-aerated reactors to achieve efficient removal. Adsorption techniques, for instance, have shown promise in batch and column studies for capturing the compound from aqueous solutions, while oxidation processes effectively mineralize it, reducing residual . Under EU REACH regulations, 2-aminophenol is restricted pursuant to Annex XVII entry 75 due to its classification as a category 2, prohibiting its use in mixtures for tattooing and permanent make-up at concentrations exceeding 0.00005%. , the EPA monitors , including potential detection of 2-aminophenol, in industrial effluents under the Clean Water Act, though it is not designated as a priority pollutant. To mitigate environmental releases, post-2020 developments in green synthesis include biocatalytic reductions for nitroarene precursors, enabling selective with reduced and emissions compared to traditional chemical routes. Its oxidation reactivity, which contributes to both natural attenuation and efficacy, further supports these abatement strategies.