65539-72-2

Upstream product

• 5707-04-0 Phenylselenyl chloride 
• 821-09-0 n-Pent-4-enyl alcohol 
• 1666-13-3 diphenyl diselenide 
• 133708-80-2 benzeneselenenyl m-nitrobenzenesulfonate 
• 81518-74-3 1-benzyloxy-4-pentene 
• 34837-55-3 Phenylselenyl bromide 
• 915127-49-0 N-phenylselenosaccharin 
• 591-50-4 iodobenzene 

Downstream Products

• 19354-27-9 methyl tetrahydrofurfuryl ether 

Relevant academic research and scientific papers

An improved phenylselenoetherification of pent-4-en-1-ol

The procedure employs phenylselenyl chloride or bromide, pent-4-en-1-ol, and additives, like pyridine and silver(I) salts, to generate the cyclic ether of tetrahydrofuran type in high yields. A catalytic amount of additive leads to higher yields, but equi

PIDA-Promoted Selective C5 C?H Selenylations of Indolines via Weak Interactions

An efficient PIDA (phenyliodine(III) diacetate)-promoted positional selective C?H selenylations of indolines with diaryl diselenides has been developed. This transformation conducted under mild reaction conditions with a broad functional group tolerance,

Synthesis, crystal and solution structures and antimicrobial screening of palladium(II) complexes with 2-(phenylselanylmethyl)oxolane and 2-(phenylselanylmethyl)oxane as ligands

Two novel Pd(II) complexes with 2-(phenylselanylmethyl)oxolane and 2-(phenylselanylmethyl)oxane as ligands were synthesized. The crystal and molecular structure of the complexes has been determined by single crystal X-ray diffraction. It turned out for bo

Time-economical synthesis of selenofunctionalized heterocycles via I2O5-mediated selenylative heterocyclization

A time-economical and robust synthesis of various selenofunctionalized heterocycles was accomplished via I2O5-mediated selenocyclizations of olefins with diselenides. Using this method, 116 selenomethyl-substituted heterocycles were

Preparation of selenofunctionalized heterocycles via iodosobenzene-mediated intramolecular selenocyclizations of olefins with diselenides

An intramolecular selenocyclizations of olefins mediated by a commercially available hypervalent iodine(III) reagent, PhIO, was developed. This method provided access to a wide range of selenenylated heterocycles under ambient conditions. The striking advantages of this protocol over all previous methods include mild reaction conditions, easy operation, good yields, high levels of functional group compatibility, large–scale application and suitability for the late-stage functionalization of complex molecules of biological importance.

Electrochemical Difunctionalization of Olefines: Access to Selenomethyl-Substituted Cyclic Ethers or Lactones

A metal- and oxidant-free electrochemical method for preparing selenomethyl-substituted cyclic ethers or lactones via difunctionalization of olefines is presented. A series of selenomethyl-substituted cyclic ethers, particularly 9- and 11- membered, selen

Automated Electrochemical Selenenylations

Integrated electrochemical reactors in automated flow systems were utilised for selenenylation reactions. The automation allowed multiple electrochemical reactions of a programmed sequence to be performed in a fully autonomous way. Many functionalised selenenylated products were synthesised in short reaction times in good to high yields.

Preparation of Heterocycles via Visible-Light-Driven Aerobic Selenation of Olefins with Diselenides

The aerobic dehydrogenative cyclization of alkenes with easily accessible diselenides facilitated by visible light is reported. Notably, the features of this transition-metal-free protocol are pronounced efficiency and practicality, good functional group

A mild and efficient procedure for alkenols oxyselenocyclization by using ionic liquids

A mild and efficient procedure for the oxyselenocyclization of unsaturated alcohols by treatment with phenylselenyl chloride using ionic liquids as solvents/catalyzers has been developed. The reaction proceeds instantaneously under mild conditions with ab

Visible-light-mediated aerobic selenation of (hetero)arenes with diselenides

The first visible-light driven aerobic oxidation for the direct selenation of (hetero)arenes has been developed at room temperature, providing an eco-friendly, atom-economical protocol to prepare unsymmetrical selenides from easily accessible diselenides.