13519-75-0

Basic information

• Product Name: N-ETHYL-4-CHLOROANILINE
• Synonyms: N-(4-CHLOROPHENYL)ETHYLAMINE;N-ETHYL-4-CHLOROANILINE;N-ETHYL-P-CHLOROANILINE;4-CHLORO-N-ETHYLANILINE;BUTTPARK 146\06-37;Ethylchloroaniline;4-Chloro-N-ethylaniline, tech;N1-ethyl-4-chloroaniline
• CAS NO: 13519-75-0
• Molecular Formula: C₈H₁₀ClN
• Molecular Weight: 155.62
• Mol File: 13519-75-0.mol

Chemical Properties

• Boiling Point: 68/0.5mm
• Flash Point: 108.9 °C
• Appearance: /
• Density: 1,12 g/cm3
• Vapor Pressure: 0.0153mmHg at 25°C
• Refractive Index: 1.5670-1.5700
• PKA: 4.50±0.32(Predicted)
• CAS DataBase Reference: N-ETHYL-4-CHLOROANILINE(CAS DataBase Reference)
• NIST Chemistry Reference: N-ETHYL-4-CHLOROANILINE(13519-75-0)
• EPA Substance Registry System: N-ETHYL-4-CHLOROANILINE(13519-75-0)

Safety Data

• Hazard Codes: Xi
• Statements: 20/21/22-36/37/38
• Safety Statements: 26-36/37/39
• Hazardous Substances Data: 13519-75-0(Hazardous Substances Data)

Usage

Uses

Used in Chemical Industry:
N-ETHYL-4-CHLOROANILINE is used as an intermediate in the synthesis of dyes and pigments for various applications, including coloring textiles, plastics, and other materials. Its role in the production process is crucial for creating a wide range of colorants that are essential in different industries.
Used in Textile Industry:
In the textile industry, N-ETHYL-4-CHLOROANILINE is used as a precursor for the development of dyes that impart color to fabrics. Its contribution to the dye manufacturing process is vital for producing vibrant and long-lasting colors on textiles.
Used in Plastics Industry:
N-ETHYL-4-CHLOROANILINE is also utilized in the plastics industry as a component in the creation of pigments that color various types of plastic materials. Its use ensures the production of plastics with consistent and stable colors, suitable for a wide array of applications.
Used in Paint and Coating Industry:
In the paint and coating industry, N-ETHYL-4-CHLOROANILINE is employed as a key intermediate for the formulation of pigments that provide color to paints and coatings. Its presence in the manufacturing process is essential for creating high-quality products with the desired color characteristics.

InChI:InChI=1/C8H10ClN/c1-2-10-8-5-3-7(9)4-6-8/h3-6,10H,2H2,1H3

Upstream product

• 1956-39-4 (E)-1-(4-chlorophenyl)ethanone oxime 
• 74-96-4 ethyl bromide 
• 106-47-8 4-chloro-aniline 
• 539-03-7 N-(4-chlorophenyl)acetamide 
• 80-40-0 ethyl ester of p-toluenesulfonic acid 
• 64-17-5 ethanol 
• 7647-01-0 hydrogenchloride 
• 69391-88-4 3-ethyl-1,3-bis-(4-chloro-phenyl)-triazene 
• 74-85-1 ethene 
• 109-92-2 ethyl vinyl ether 
• 75-03-6 ethyl iodide 
• 64-19-7 acetic acid 
• 15481-55-7 4-Nitrobenzenesulfonic acid ethyl ester 
• 13519-67-0 4-chloro-N-ethylformanilide 

Downstream Products

• 99857-75-7 N-ethyl-N-(4-chloro-phenyl)-N',N'-dimethyl-urea 
• 2873-89-4 4-chloro-N,N-diethylaniline 
• 601-72-9 4-chloro-benzenesulfonic acid-(N-ethyl-4-chloro-anilide) 
• 56978-44-0 chloro-acetic acid-(N-ethyl-4-chloro-anilide) 
• 109453-51-2 toluene-4-sulfonic acid-(N-ethyl-4-chloro-anilide) 

Relevant articles and documents

Evidence for a hydrogen abstraction mechanism in P450-catalyzed N-dealkylations

The experimental evidence presented in this manuscript suggest against the widely accepted single electron/proton transfer mechanism for P450 catalyzed N-dealkylations and provides strong support for a hydrogen atom abstraction mechanism.

Synthese de N-Alkyl-arylamines par Thermolyse ou Photolyse d'Alkyl-3-diaryl-1,3-triazenes

The thermolysis of 3-alkyl-1,3-bis(p-chlorophenyl)triazenes in benzene or methanol leads to the formation of N-alkyl-p-chloroanilines (2) in 19-50 percent yield, N-alkyl-bis(p-chlorophenyl)amines (3) in 7.5-15.5 percent yield and 4,4'-dichlorobiphenyle (4) in 1-7 percent yield; besides with benzene as the substrate, 4-chlorobiphenyle (5) (12-20 percent yield) was also formed.The photolysis in methanol gives only the N-alkyl-p-chloroanilines (2) in 32-40 percent yield.In these two cases the results are consistent with a radical pair formation in a solvent cage, recombination (thermolysis) and/or diffusion (thermolysis and photolysis) with intermolecular abstraction of hydrogen.A free radical chain mechanism is involved in the photolytic process and the quantum yield is high.

Novel hybrid conjugates with dual estrogen receptor α degradation and histone deacetylase inhibitory activities for breast cancer therapy

Hormone therapy targeting estrogen receptors is widely used clinically for the treatment of breast cancer, such as tamoxifen, but most of them are partial agonists, which can cause serious side effects after long-term use. The use of selective estrogen receptor down-regulators (SERDs) may be an effective alternative to breast cancer therapy by directly degrading ERα protein to shut down ERα signaling. However, the solely clinically used SERD fulvestrant, is low orally bioavailable and requires intravenous injection, which severely limits its clinical application. On the other hand, double- or multi-target conjugates, which are able to synergize antitumor activity by different pathways, thus may enhance therapeutic effect in comparison with single targeted therapy. In this study, we designed and synthesized a series of novel dual-functional conjugates targeting both ERα degradation and histone deacetylase inhibiton by combining a privileged SERD skeleton 7-oxabicyclo[2.2.1]heptane sulfonamide (OBHSA) with a histone deacetylase inhibitor side chain. We found that substituents on both the sulfonamide nitrogen and phenyl group of OBHSA unit had significant effect on biological activities. Among them, conjugate 16i with N-methyl and naphthyl groups exhibited potent antiproliferative activity against MCF-7 cells, and excellent ERα degradation activity and HDACs inhibitory ability. A further molecular docking study indicated the interaction patterns of these conjugates with ERα, which may provide guidance to design novel SERDs or PROTAC-like SERDs for breast cancer therapy.

Halogenated method of aromatic compound

The invention belongs to the field of organic synthesis, and particularly relates to synthesis of aromatic halogens, in particular to arylamine. The invention discloses a synthesis method of a corresponding ortho-halogenated product from aromatic compounds such as carbazole and phenol. The method comprises the following steps: adding a metal sulfonate salt catalyst, aromatic amine, carbazole, phenol and other hydrogen - heteroatom-containing aromatic compound reaction substrates, a halogenation reagent and a reaction solvent at a specific reaction temperature. After the drying agent is dried, the yield of the reaction product and the nuclear magnetic characterization determining structure are determined by column chromatography. The reaction product yield is determined by gas chromatography. By adopting the method, under the cheap metal salt catalyst, a plurality of ortho-substituted brominated and chloro products can be obtained with moderate to excellent yield.

Highly Active Ni Nanoparticles on N-doped Mesoporous Carbon with Tunable Selectivity for the One-Pot Transfer Hydroalkylation of Nitroarenes with EtOH in the Absence of H2

Cost-effective and environmentally friendly conversion of nitroarenes into value-added products is desirable but still challenging. In this work, highly dispersed Ni nanoparticles (NPs) supported on N-doped mesoporous carbon (Ni/NC-x) were synthesized via novel ion exchange-pyrolysis strategy. Their catalytic performance was investigated for one-pot transfer hydroalkylation of nitrobenzene (NB) with EtOH in absence of H2. Interestingly, the catalytic performance could be easily manipulated by tuning the morphology and electronic state of Ni NPs via varying the pyrolysis temperature. It was found that the Ni/NC-650 achieved 100 % nitrobenzene conversion and approx. 90 % selectivity of N,N-diethyl aniline at 240 °C for 5 h, more active than those of homogeneous catalysts or supported Ni catalysts prepared by impregnation (Ni/NC-650-IM, Ni/SiO2). This can be ascribed to the higher dispersion and better reducibility as well as richer surface basicity of the catalyst. More interestingly, the Ni/NC-650 catalyst achieved complete conversion of various nitroarenes, yielding imines, secondary amines, or tertiary amines selectively by simply controlling the reaction temperature at 180, 200 and 240 °C, respectively. The one-pot hydrogen-free process with non-noble metal catalysts, as demonstrated in this work, shows great promise for selective conversion of nitroarenes with ethanol to various anilines at industrial scale, from an economic, environmental, and safety viewpoint.

A highly efficient Co-based catalyst fabricated by coordination-assisted impregnation strategy towards tandem catalytic functionalization of nitroarenes with various alcohols

A well-defined hexamethylenetetramine (abbreviated as HMTA) based two-dimensional (2D) MOFs metalloligand (termed Zn-HMTA), with free uncoordinated tertiary amine groups, has been synthesized via solution diffusion method for the first time. The crystal structure of 2D Zn-HMTA metalloligand was determined by the single crystal X-ray diffraction (SCXRD). The SCXRD and X-ray photoelectron spectroscopy (XPS) analyses have revealed that the 2D Zn-HMTA metalloligand is rich in- free tertiary amine groups, which are of strong coordination ability to transition metal ions (e.g. Ni2+, Co2+, Zn2+, Cu2+). As a result, a 2D bimetallic Co@Zn-HMTA MOFs was synthesized via coordination-assisted impregnation (CAI) strategy attributed to the unique feature of strong coordinated ability of free tertiary amine groups. Furthermore, a series of self-supported Co-ZnO-CN nanocatalysts were afforded upon the as-synthesized Co@Zn-HMTA MOFs served as a self-sacrificial template for pyrolysis at different temperatures. The optimized catalyst (termed as Co-ZnO@CN-CAI) demonstrated the excellent catalytic performance for hydrogenation-alkylation tandem reaction in comparison with the classic ZnO@CN composite (derived from Zn-HMTA MOFs) supported metallic Co catalyst (Co-ZnO@CN-IWI) prepared by incipient wetness impregnation method. Moreover, the kinetic study was also performed to confirm that the alkylation is the rate-determining step in the hydrogenation-alkylation tandem reaction. The origin of enhanced catalytic performance of Co-ZnO@CN-CAI and the role of Co@Zn-HMTA MOFs precursor have been explored by way of various characterizations, e.g. HADDF-STEM-EDS, SEM-EDS, 13C MAS NMR, XRD, Raman and XPS, etc. It is anticipated that the prepared low-cost and easily prepared 2D Zn-HMTA metalloligand will become a general template for synthesis of highly self-supported catalysts with coordination-assisted impregnation strategy (CAI) for various catalytic reactions.

Diethylsilane as a Powerful Reagent in Au Nanoparticle-Catalyzed Reductive Transformations

Diethylsilane (Et2SiH2), a simple and readily available dihydrosilane, that exhibits superior reactivity, as compared to monohydrosilanes, in a series of reductive transformations catalyzed by recyclable and reusable Au nanoparticles (1 mol-%) supported on TiO2. It reduces aldehydes or ketones almost instantaneously at ambient conditions. It can be used in a one pot rapid reductive amination procedure, in which premixing of aldehyde and amine is required prior to the addition of the reducing agent and the catalyst, even in a protic solvent. An unprecedented method for the synthesis of N-arylisoindolines is also shown in the reductive amination between o-phthalaldehyde and anilines. In this transformation, it is proposed that the intermediate N,2-diphenylisoindolin-1-imines are reduced stepwise to the isoindolines. Finally, Et2SiH2 readily reduces amides into amines in excellent yields and shorter reaction times relative to previously known analogous nano Au(0)-catalyzed protocols.

Exploring Opportunities for Platinum Nanoparticles Encapsulated in Porous Liquids as Hydrogenation Catalysts

The unusual combination of characteristics observed for porous liquids, which are typically associated with either porous solids or liquids, has led to considerable interest in this new class of materials. However, these porous liquids have so far only been investigated for their ability to separate and store gases. Herein, the catalytic capability of Pt nanoparticles encapsulated within a Type I porous liquid (Pt@HS-SiO2 PL) is explored for the hydrogenation of several alkenes and nitroarenes under mild conditions (T=40 °C, PH2=1 atm). The different intermediates in the porous liquid synthesis (i.e., the initial Pt@HS-SiO2, the organosilane-functionalized intermediate, and the final porous liquid) are employed as catalysts in order to understand the effect of each component of the porous liquid on the catalysis. For the hydrogenation of 1-decene, the Pt@HS-SiO2 PL catalyst in ethanol has the fastest reaction rate if normalized with respect to the concentration of Pt. The reaction rate slows if the reaction is completed in a “neat” porous liquid system, probably because of the high viscosity of the system. These systems may find application in cascade reactions, in particular, for those with mutually incompatible catalysts.

Direct N-Alkylation/Fluoroalkylation of Amines Using Carboxylic Acids via Transition-Metal-Free Catalysis

A scalable protocol of direct N-mono/di-alkyl/fluoroalkylation of primary/secondary amines has been constructed with various carboxylic acids as coupling agents under the catalysis of a simple air-tolerant inorganic salt, K3PO4. Advantageous features include 100 examples, 10 drugs and drug-like amines, fluorinated complex tertiary amines, gram-scale synthesis and isotope-labelling amine, thus demonstrating the potential applicability in industry of this methodology. The involvement of relatively less reactive silicon-hydride compared with the traditional reactive metal-hydride or boron-hydride species required to reduce the amide intermediates presumably contributes to the remarkable functional group compatibility. (Figure presented.).

B(C6F5)3-Catalyzed Deoxygenative Reduction of Amides to Amines with Ammonia Borane

The first B(C6F5)3-catalyzed deoxygenative reduction of amides into the corresponding amines with readily accessible and stable ammonia borane (AB) as a reducing agent under mild reaction conditions is reported. This metal-free protocol provides facile access to a wide range of structurally diverse amine products in good to excellent yields, and various functional groups including those that are reduction-sensitive were well tolerated. This new method is also applicable to chiral amide substrates without erosion of the enantiomeric purity. The role of BF3 ? OEt2 co-catalyst in this reaction is to activate the amide carbonyl group via the in situ formation of an amide-boron adduct. (Figure presented.).