339175-65-4

Upstream product

• 96802-17-4 1,4-diiodo-2,5-diethylbenzene 
• 1066-54-2 trimethylsilylacetylene 
• 105-05-5 1,4-diethylbenzene 
• 937-30-4 4-ethylacetophenone 

Downstream Products

• 339175-46-1 4-[2,5-diethyl-4-(4-aminophenylethynyl)phenylethynyl]aniline 
• 339175-66-5 4-[2,5-diethyl-4-(4-nitrophenylethynyl)phenylethynyl]nitrobenzene 
• 421554-34-9 thioacetic acid S-{4-[4-(4-acetylsulfanyl-phenylethynyl)-2,5-diethyl-phenylethynyl]-phenyl} ester 

Relevant academic research and scientific papers

Synthesis and spectroscopic study of phenylenee (poly) ethynylenes substituted by amino or amino/cyano groups at terminal(s):Electronic effect of cyano group on charge-transfer excitation of acetylenic φ-systems

To gain insight into substituent electronic effect on charge-transfer excitation of acetylenic p-systems, phenylenee(poly)ethynylenes substituted by Ph2N or Ph2N/cyano groups were synthesized by combination of Sonogashira coupling and double elimination protocol of b-substituted sulfones.These substituted phenyleneethynylenes showed large molar absorption coefficients 3, and emitted strong fluorescence upon UV light irradiation.Phenylenee(poly)ethynylenes, which involve butadiyne or hexatriyne motifs, emitted fluorescence in remarkably lower fluorescence quantum yields FF as their polyethynylene motifs e(C^C)ne expanded.The drastic decrease of fluorescence quantum yields FF were explained in terms of increasing nonradiative reaction rate constants knr, which had been determined by the corresponding fluorescence quantum yields F F and lifetime values s.The emission underwent a large bathochromic shift in polar solvents because the charge-separated excited state is more stabilized than the ground state.Comparison of slope values r in Lippert/Mataga plot for the Ph2N and Ph2N/cyano-substituted phenylenee(poly)ethynylenes revealed that the latter underwent large change of dipole moments upon photo-excitation although highly expanded acetylenic p-systems with cyano group did little.

Phenylene ethynylene diazonium salts as potential self-assembling molecular devices

(matrix presented) Functionalized diazonium salts for molecular electronic devices are prepared by the reaction of the corresponding anilines with NOBF4 in sulfolane-acetonitrile solvent.

Synthesis and preliminary testing of molecular wires and devices

Presented here are several convergent synthetic routes to conjugated oligo(phenylene ethynylene)s. Some of these oligomers are free of functional groups, while others possess donor groups, acceptor groups, porphyrin interiors, and other heterocyclic interiors for various potential transmission and digital device applications. The syntheses of oligo(phenylene ethynylene)s with a variety of end groups for attachment to numerous metal probes and surfaces are presented. Some of the functionalized molecular systems showed linear, wire-like, current versus voltage (I(V)) responses, while others exhibited nonlinear I(V) curves for negative differential resistance (NDR) and molecular random access memory effects. Finally, the syntheses of functionalized oligomers are described that can form self-assembled monolayers on metallic electrodes that reduce the Schottky barriers. Information from the Schottky barrier studies can provide useful insight into molecular alligator clip optimizations for molecuar electronics.