5285-74-5

Basic information

• Product Name: Thiocyanic acid, 4-methylphenyl ester
• CAS NO: 5285-74-5
• Molecular Formula: C8H7NS
• Molecular Weight: 149.216
• Mol File: 5285-74-5.mol

Chemical Properties

• CAS DataBase Reference: Thiocyanic acid, 4-methylphenyl ester(CAS DataBase Reference)
• NIST Chemistry Reference: Thiocyanic acid, 4-methylphenyl ester(5285-74-5)
• EPA Substance Registry System: Thiocyanic acid, 4-methylphenyl ester(5285-74-5)

Safety Data

• Hazardous Substances Data: 5285-74-5(Hazardous Substances Data)

Upstream product

• 64-17-5 ethanol 
• 106-49-0 p-toluidine 
• 64-19-7 acetic acid 
• 15199-26-5 N-((4-methylphenyl)thio)phthalimide 
• 143-33-9 sodium cyanide 
• 933-00-6 p-methylbenzenesulfenyl chloride 
• 2408-36-8 lithium cyanide 
• 75-01-4 chloroethylene 
• 333-20-0 potassium thioacyanate 
• 459-44-9 4-methylbenzenediazonium tetrafluoroborate 
• 75-35-4 1,1-Dichloroethylene 
• 2942-58-7 diethyl cyanophosphonate 
• 824-79-3 sodium 4-methylbenzenesulfinate 
• 1666-17-7 benzaldehyde p-toluenesulfonylhydrazone 

Downstream Products

• 103-19-5 di(p-tolyl) disulfide 
• 71215-88-8 3-nitro-4-thiocyanatotoluene 
• 95062-72-9 S-(4-methylphenyl) thiocarbamate 
• 106-45-6 para-thiocresol 
• 3996-29-0 2-[(4-methylphenyl)thio]acetic acid 
• 34126-48-2 O-Methyl-S-(p-tolyl)-thioiminocarbonat 
• 33046-45-6 1-phenyl-2-(p-tolylthio)ethanone 
• 139177-79-0 3-<(p-tolylthio)aminomethylene>pentane-2,4-dione 
• 3699-01-2 4-tolyl phenyl sulfide 
• 99433-27-9 1-(4-(4-tolylsulfanylphenyl))ethanone 
• 42330-81-4 rac-(R)-2-phenyl-2-(p-tolylthio)ethan-1-ol 
• 102834-18-4 (+/-)-cis-2-p-tolylsulfanyl-cyclohexanol 
• 102834-18-4 trans-(±)-2-(p-tolylthio)cyclohexanol 

Relevant articles and documents

Temperature-Controlled Chemoselective Synthesis of Thiosulfonates and Thiocyanates: Novel Reactivity of KXCN (X=S, Se) towards Organosulfonyl Chlorides

An efficient chemoselective protocol has been developed for the synthesis of thiosulfonates and thiocyanates by employing cost effective and commercially available organosulfonyl chlorides with potassium thio-/selenocyanate. The strategy offered the thiosulfonates and thiocyanates selectively by tuning the equivalents of KSeCN and optimizing the reaction temperature. On the other hand, thiosulfonates were obtained as sole products when organosulfonyl chlorides were treated with KSCN. Furthermore, the syntheses of diarylthioethers and aryl(heteroaryl) thioethers were carried out as a part of synthetic application of newly prepared arylthiocyanates.

Straightforward Access to Thiocyanates via Dealkylative Cyanation of Sulfoxides

Thiocyanates, versatile building blocks in organic synthesis, are shown to be easily accessible via an interrupted Pummerer reaction of sulfoxides. This facile dealkylative functionalization proceeds under mild conditions through electrophilic activation of the sulfoxide partner. The resulting thiocyanate itself can serve as a handle for diversification in a straightforward one-pot procedure.

Synthesis of Thio-/Selenopyrrolines via SnCl4-Catalyzed (3+2)-Cycloadditions of Donor-Acceptor Cyclopropanes with Thio-/Selenocyanates

A straightforward protocol has been developed to access thio-/selenopyrrolines through a (3+2)-cycloaddition of aryl thio-/selenocyanates with donor-acceptor cyclopropanes (DACs) in the presence of SnCl4 as a Lewis acid catalyst. Further, good chemoselectivity was observed when DACs were treated with 3-cyano phenyl thiocyanate. These results suggest that thiocyanate is more reactive than nitrile moiety in such (3+2)-cycloaddition reactions.

Selectfluor-initiated cyanation of disulfides to thiocyanates

A Selectfluor-initiated cyanation of disulfides to thiocyanates has been developed. In this process, Selectfluor was employed as the oxidant and trimethylsilyl cyanide was used as the cyanation reagent. It provides an eco-friendly and simple way to synthesize the thiocyanates.

An electrochemical method for deborylative seleno/thiocyanation of arylboronic acids under catalyst- And oxidant-free conditions

An electrochemical deborylative seleno/thiocyanation of arylboronic acids has been well established to synthesize the corresponding aryl seleno/thiocyanates with good functional group tolerance under ambient conditions. A gram-scale reaction has been performed to highlight the advantages of the protocol. Preliminary mechanistic studies indicate that the oxidation of the seleno/thiocyanate anion occurs prior to that of the arylboronic acid substrate in galvanostatic mode, and that free radicals are involved in the process.

Fluorium-Initiated Dealkylative Cyanation of Thioethers to Thiocyanates

Thioethers are converted to thiocyanates via fluorium-initiated dealkylative cyanation. Selectfluor is used as the oxidant, and trimethylsilyl cyanide is used as the cyanation reagent. The well-streamlined procedure is user-friendly, operationally simple, and step-economical. The current mechanistic studies show that the sulfur radical cation and cyano radical are both involved. They combine to deliver cyanosulfonium, an intermediate toward thiocyanate after dealkylation. Alternatively, a nucleophilic mechanism is also possible. Our dealkyaltive cyanation is also efficient in synthesizing thiocyanates with strongly electrophilic functionalities.

N -Thiocyanato-dibenzenesulfonimide: A new electrophilic thiocyanating reagent with enhanced reactivity

A novel electrophilic thiocyanating reagent, N-thiocyanato-dibenzenesulfonimide, was prepared and exhibited enhanced electrophilicity with a wide scope of substrates. Thus, it reacted with activated aromatics such as phenols, indoles, anilines and anisoles without a catalyst giving the corresponding thicyanate derivatives in high yields, while TfOH for unactivated arenes and hetero aromatics and Zn(OTf)2 for ketones was used as the catalyst, respectively. It is noteworthy that internal alkenes and styrenes were bifunctionalized giving 1,2-amino thiocyanates in high yields.

Electrochemical ipso-Thiocyanation of Arylboron Compounds

An operationally simple electrochemical method for the transition-metal-free ipso-thiocyanation of arylboronic acids and aryl trifluoroborates has been developed. The SCN electrophile is generated in situ by anodic oxidation of thiocyanate anions, which avoids formation of salt waste and prevents unwanted side reactions arising from chemical oxidants. The reaction proceeds regiospecifically, and the scope extends to non-activated aromatic systems. (Figure presented.).

Preparation method for thiocyanide compound

The invention discloses a preparation method for a thiocyanide compound. The preparation method comprises the following steps: taking a sulfhydryl compound, thiocyanate as raw materials, taking rose-bengal, eosine Y or eosin B as a catalyst, performing illumination, generating a thiocyanide compound after the illumination reaction. According to the preparation method provided by the invention, thiocyanide is decomposed into thiocyanate ions; the sulfhydryl compound generates sulfhydryl radical under the action of light and the catalyst, and the sulfhydryl radical is used for attacking carbon atoms in thiocyanate ions to obtain a intermediate; sulfide is removed from the intermediate to obtain the thiocyanide compound. The rose-bengal, the eosine Y or the eosin B used by the method containno heavy metal ion, and the adverse effect on the performance of the thiocyanide compound by the heavy metal ion residue is avoided; in addition, the catalyst is easily removed, so that a favorable condition is provided for the preparation of the thiocyanide compound with higher purity.

Direct Photocatalytic S-H Bond Cyanation with Green cN Source

Herein we report a novel C-S bond cleavage and reconstruction strategy for the synthesis of thiocyanates through direct photocatalytic S-H bond cyanation from thiols and inorganic thiocyanate salts. In our strategy, the unprecedented example of cutting off C-S bond of SCN- to deliver the green CN sources is demonstrated. This transformation features nontoxic and inexpensive CN sources, available starting materials, metal-/base-/ligand-/peroxide-free, high step economy and mild conditions. It leads to the construction of various thiocyanates and some medicinally and biologically active thiocyanate-containing molecules.