86-53-3

Basic information

• Product Name: 1-Cyanonaphthalene
• Synonyms: α-Napthyl cyanide;1-Naphtyl cyanide;1-Cyanonaphthalene,98%;α-naphthyl cyanide NCN;1-Cyanonaphthalene, 98% 2.5GR;1-Cyanonaphthalene 1-Naphthylcyanide;Naphthalene-1-carbonitrile, 1-Cyanonaphthalene;1-Cyanonaphthalene 98%
• CAS NO: 86-53-3
• Molecular Formula: C₁₁H₇N
• Molecular Weight: 153.18
• EINECS: 201-679-8
• Product Categories: Naphthalene derivatives
• Mol File: 86-53-3.mol

Chemical Properties

• Melting Point: 36-38 °C(lit.)
• Boiling Point: 299 °C(lit.)
• Flash Point: 92°C/0.2mm
• Appearance: Reddish-yellow to red-purple/Liquid or Low Melting Solid
• Density: 1.1113
• Refractive Index: 1.6298
• Solubility: soluble in Methanol
• BRN: 971255
• CAS DataBase Reference: 1-Cyanonaphthalene(CAS DataBase Reference)
• NIST Chemistry Reference: 1-Cyanonaphthalene(86-53-3)
• EPA Substance Registry System: 1-Cyanonaphthalene(86-53-3)

Safety Data

• Hazard Codes: Xn,Xi
• Statements: 20/21/22-36/37/38-20/21
• Safety Statements: 26-37/39-23-36/37-36
• RIDADR: UN 3439 6.1/PG 1
• WGK Germany: 3
• RTECS: QL5976300
• TSCA: Yes
• HazardClass: 6.1
• PackingGroup: III
• Hazardous Substances Data: 86-53-3(Hazardous Substances Data)

Usage

Chemical Properties

White to yellow solid

Synthesis Reference(s)

The Journal of Organic Chemistry, 6, p. 795, 1941 DOI: 10.1021/jo01206a002Synthetic Communications, 26, p. 291, 1996 DOI: 10.1080/00397919608003617

InChI:InChI=1/C11H7N/c12-8-10-6-3-5-9-4-1-2-7-11(9)10/h1-7H

Upstream product

• 1240-37-5 N,N'-bis(1-naphthyl)thiourea 
• 91-20-3 naphthalene 
• 460-19-5 ethanedinitrile 
• 2243-81-4 1-naphthylcarboxamide 
• 3007-97-4 ethyl 1-naphthoate 
• 6330-51-4 1-naphthylformamide 
• 85-47-2 1-naphthalenesulfonic acid 
• 151-50-8 potassium cyanide 
• 3815-24-5 N,N-dimethyl-1-naphthamide 
• 4004-51-7 tri-1-naphthyl phosphate 
• 144-62-7 oxalic acid 
• 134-32-7 1-amino-naphthalene 
• 703-55-9 1-naphthylmagnesiumbromide 
• 506-77-4 cyanogen chloride 

Downstream Products

• 1484-12-4 N-methylcarbazole 
• 86-74-8 9H-carbazole 
• 15719-64-9 methylammonium carbonate 
• 1591-44-2 (4-chlorophenyl)(naphthalen-1-yl)methanone 
• 39070-92-3 (4-methoxyphenyl)(naphthalen-1-yl)methanone 
• 605-78-7 bis(naphthalen-1-yl)methanone 
• 24092-46-4 (3-chloro-phenyl)-[1]naphthyl ketone 
• 2876-60-0 1-(naphthalen-1-yl)pentan-1-one 
• 941-98-0 1'-naphthacetophenone 
• 2876-58-6 1-n-octanoylnaphthalene 
• 2876-62-2 1-naphthalen-1-ylbutan-1-one 
• 26189-36-6 [1,1'-biphenyl]-4-yl(naphthalen-1-yl)methanone 
• 13623-57-9 2-naphthalen-1-yl-4,5-dihydro-1H-imidazole 
• 2876-61-1 1-(naphthalen-1-yl)hexan-1-one 

Relevant articles and documents

Ligand properties of aromatic azines: C-H activation, metal induced disproportionation and catalytic C-C coupling reactions

The reaction of aromatic azines with Fe2(CO)9 yields dinuclear iron carbonyl cluster compounds as the main products. The formation of these compounds may be rationalized by a C-H activation reaction at the aromatic substituent in ortho position with respect to the exocyclic C-N double bond followed by an intramolecular shift of the corresponding hydrogen atom toward the former imine carbon atom. The second imine function of the ligand does not react. Additional products arise from the metal induced disproportionation of the azine into a primary imine and a nitrile. So also one of the imine C-H bonds may be activated during the reaction. Depending on the aromatic substituent of the azine ligands iron carbonyl complexes of the disproportionation products are isolated and characterized by X-ray crystallography. C-C coupling reactions catalyzed by Ru3(CO)12 result in the formation of ortho-substituted azines. In addition, ortho-substituted nitriles are identified as side-products showing that the metal induced disproportionation reaction also takes place under catalytic conditions.

Highly dispersed Co species in N-doped carbon enhanced the aldehydes ammoxidation reaction activity

Developing environmentally friendly catalysts with high activity for the ammoxidation of aromatic aldehydes to aromatic nitriles is greatly important for this industrial transformation. Herein, natural vitamin B12 was used as a carbon source for the preparation of a cobalt- and nitrogen-doped catalyst precursor, which was pyrolyzed at different temperatures to obtain cobalt- and nitrogen-doped carbon (Co@NC-T) (T denotes pyrolysis temperature) catalysts. The Co@NC-800 exhibited excellent activity and selectivity in the ammoxidation of aromatic aldehydes with ammonium carbonate to aromatic nitriles compared to the Co@NC-700, Co@NC-600 and Co@NC-500 catalysts. The high catalytic performance of Co@NC-800 could be due to the presence of the low-density electron cloud of the highly dispersed Co species, which could interact with the benzene ring of benzaldehyde bearing p-π conjugate, thereby promoting the adsorption and activation of benzaldehyde. Consequently, the activated benzaldehyde reacted with amino groups that were decomposed from ammonium carbonate and subsequently underwent a dehydration process to form nitriles.

Nitrile Synthesis via Desulfonylative-Smiles Rearrangement

Herein, we designed a simple nitrile synthesis from N-[(2-nitrophenyl)sulfonyl]benzamides via base-promoted intramolecular nucleophilic aromatic substitution. The process features redox-neutral conditions as well as no requirement of toxic cyanide species and transition metals. Our process shows broad scope and various functional group compatibility, affording a variety of (hetero)aromatic nitriles in good to excellent yields.

Cyanide-Free Cyanation of sp2 and sp-Carbon Atoms by an Oxazole-Based Masked CN Source Using Flow Microreactors

This work reports a cyanide-free continuous-flow process for cyanation of sp2 and sp carbons to synthesize aryl, vinyl and acetylenic nitriles from (5-methyl-2-phenyloxazol-4-yl) boronic acid [OxBA] reagent as a sole source of carbon-bound mask

Decarbonylative Synthesis of Aryl Nitriles from Aromatic Esters and Organocyanides by a Nickel Catalyst

A decarbonylative cyanation of aromatic esters with aminoacetonitriles in the presence of a nickel catalyst was developed. The key to this reaction was the use of a thiophene-based diphosphine ligand, dcypt, permitting the synthesis of aryl nitrile without the generation of stoichiometric metal- or halogen-containing chemical wastes. A wide range of aromatic esters, including hetarenes and pharmaceutical molecules, can be converted into aryl nitriles.

A facile and versatile electro-reductive system for hydrodefunctionalization under ambient conditions

A general electrochemical system for reductive hydrodefunctionalization is described, employing the inexpensive and easily available triethylamine (Et3N) as a sacrificial reductant. This protocol is characterized by facile operation, sustainable conditions, and exceptionally wide substrate scope covering the cleavage of C-halogen, N-S, N-C, O-S, O-C, C-C and C-N bonds. Notably, the selectivity and capability of reduction can be conveniently switched by simple incorporation or removal of an alcohol as a co-solvent.

CuO-catalyzed conversion of arylacetic acids into aromatic nitriles with K4Fe(CN)6 as the nitrogen source

Readily available CuO was demonstrated to be effective as the catalyst for the conversion of arylacetic acids to aromatic nitriles with non-toxic and inexpensive K4Fe(CN)6 as the nitrogen source via the complete cleavage of the C[tbnd]N triple bond. The present method allowed a series of arylacetic acids including phenylacetic acids, naphthaleneacetic acids, 2-thiopheneacetic acid and 2-furanacetic acid to be converted into the targeted products in low to high yields.

Recyclable and Reusable Pd(OAc)2/XPhos–SO3Na/PEG-400/H2O System for Cyanation of Aryl Chlorides with Potassium Ferrocyanide

Pd(OAc)2/XPhos–SO3Na in a mixture of poly(ethylene glycol) (PEG-400) and water is shown to be a highly efficient catalyst for the cyanation of aryl chlorides with potassium ferrocyanide. The reaction proceeded smoothly at 100 or 120?oC with K2CO3 or KOAc as base, delivering a variety of aromatic nitriles in good to excellent yields. The isolation of the crude products is facilely performed by extraction with cyclohexane and more importantly, both expensive Pd(OAc)2 and XPhos–SO3Na in PEG-400/H2O system could be easily recycled and reused at least six times without any apparent loss of catalytic efficiency. Graphical Abstract: Palladium-catalyzed cyanation of aryl chlorides with potassium ferrocyanide leading to aryl nitriles by using Pd(OAc)2/XPhos–SO3Na/PEG-400/H2O as a highly efficient and recyclable catalytic system is described.[Figure not available: see fulltext.]

Cu2O-Catalyzed Conversion of Benzyl Alcohols Into Aromatic Nitriles via the Complete Cleavage of the C≡N Triple Bond in the Cyanide Anion

Nitrogen transfer from cyanide anion to an aldehyde is emerging as a promising method for the synthesis of aromatic nitriles. However, this method still suffers from a disadvantage that a use of stoichiometric Cu(II) or Cu(I) salts is required to enable the reaction. As we report herein, we overcame this drawback and developed a catalytic method for nitrogen transfer from cyanide anion to an alcohol via the complete cleavage of the C≡N triple bond using phen/Cu2O as the catalyst. The present condition allowed a series of benzyl alcohols to be smoothly converted into aromatic nitriles in moderate to high yields. In addition, the present method could be extended to the conversion of cinnamic alcohol to 3-phenylacrylonitrile.

Selective oxidation of alcohols to nitriles with high-efficient Co-[Bmim]Br/C catalyst system

An efficient method for catalyzing the ammoxidation of aromatic alcohols to aromatic nitriles was developed, in which a new heterogeneous catalyst based on transition metal elements was employed, the new catalyst was named Co-[Bmim]Br/C-700 and then characterized by X-ray photo-electronic spectroscopy, transmission electron microscope and X-ray diffraction. The reaction was carried out by two consecutive dehydrogenations under the catalysis of Co-[Bmim]Br/C-700, which catalytically oxidized the alcohol to the aldehyde, and then the aldehyde was subjected to ammoxidation to the nitrile. The catalyst system was suitable for a wide range of substrates and nitriles obtained in high yields, especially, the conversion rate of benzyl alcohol, 4-methoxybenzyl alcohol, 4-chlorobenzyl alcohol and 4-nitrobenzyl alcohol reached 100%. The substitution of ammonia and oxygen for toxic cyanide to participate in the reaction accords with the theory of green chemistry.