41907-41-9

Upstream product

• 147-93-3 Thiosalicylic acid 
• 107-13-1 acrylonitrile 
• 61727-30-8 2,3-Dihydro-benzo[b]thiepine-4,5-dione 4-oxime 
• 2417-90-5 bromopropionitrile 

Downstream Products

• 147-93-3 Thiosalicylic acid 
• 107-13-1 acrylonitrile 
• 181118-27-4 2-(2-cyanoethylsulfanyl)benzaldehyde 
• 181118-26-3 3-((2-(hydroxymethyl)phenyl)thio)propanenitrile 
• 362690-24-2 3-(2-{[(pyridin-2-ylmethyl)-amino]-methyl}-phenylsulfanyl)-propionitrile 
• 362690-27-5 3-(2-{[(6-methyl-pyridin-2-ylmethyl)-amino]-methyl}-phenylsulfanyl)-propionitrile 
• 217962-06-6 N-(2-mercaptobenzyl)-N,N-bis(2-pyridylmethyl)amine 
• 362690-25-3 N-(2-(3-propionitilemercapto)benzyl)-N,N-bis(2-pyridylmethyl)amine 
• 362690-26-4 3-(2-{[(6-methyl-pyridin-2-ylmethyl)-pyridin-2-ylmethyl-amino]-methyl}-phenylsulfanyl)-propionitrile 
• 362690-28-6 3-(2-{[bis-(6-methyl-pyridin-2-ylmethyl)-amino]-methyl}-phenylsulfanyl)-propionitrile 

Relevant academic research and scientific papers

Paramagnetic NMR investigations of high-spin nickel(II) complexes. Controlled synthesis, structural, electronic, and magnetic properties of dinuclear vs mononuclear species

New dissymmetric tertiary amines (N3SR) with varying N/S donor sets have been synthesized to provide mono- and dinuclear complexes. Acetate ions are used to complete the octahedral coordination sphere around nickel(II) atom(s). The facile conversion of mononuclear to dinuclear systems can be controlled to produce either mono- or dinuclear complexes from the same ligand. The dinuclear complex a(BPh4)2 ([Ni2(N3SSN3)(OAc)2] (BPh4)2) has been characterized in the solid state by X-ray diffraction techniques as solvate: a(BPh4)2·1/2[5(CH3OH)· (CH3CN)·(CH3CH2OH)]. The two Ni atoms are six-coordinated and bridged by a disulfide group and two bidentate acetates. Magnetic susceptibility reveals a weak ferromagnetic exchange interaction between the two Ni atoms with J = 2.5(7) cm-1. UV-vis studies suggest that the six coordinated structure persists in solution. The 1H NMR spectrum of a(BPh4)2 exhibits sharp significantly hyperfine shifted ligand signals. A complete assignment of resonances is accomplished by a combination of methods: 2D-COSY experiments, selective chemical substitution, and analysis of proton relaxation data. Proton isotropic hyperfine shifts are shown to originate mainly from contact interactions and to intrinsically contain a small J-magnetic coupling and/or zero-field splitting contribution. A temperature dependence study of longitudinal relaxation times indicates that a very unusual paramagnetic Curie dipolar mechanism is the dominant relaxation pathway in these weakly ferromagnetically spin-coupled dinickel(II) centers. The mononuclear nickel(II) analogue exhibits extremely broader 1H NMR signals and only partial analysis could be performed. These data are consistent with a shortening of electronic relaxation times in homodinuclear compounds with respect to the corresponding mononuclear species.

Elimination reactions of β-Cyano Thioethers: Evidence for a Carbanion Intermediate and a Change in Rate-Limiting Step

The addition reactions of thiol anions to form adducts with acrylonitrile (1), 1-chloroacrylonitrile (2), and fumaronitrile (3) and the corresponding elimination reactions were examined in aqueous solution, generally containing 8.3percent Me2SO at 25 deg C.Deuterium exchange into the methanethiol and thiosalicylate adducts of 1 is faster than elimination.Deuterium exchange causes biphasic kinetics for elimination reactions in D2O of the p-nitrothiophenol, but not of the pentafluorothiophenol, adducts 1 and 2.The kinetic solvent deuterium isotope effects of knHOH/knDOD = 2.0 for addition of thiosalicylate to form 3 and 1.1-1.2 for addition of β-mercaptoethanol and thioacetic acid anions to form 1 are smaller than the product discrimination isotope effects of kH/kD = 3.2, 2.8 and 3.2 for these reactions.These differences show that the reactions proceed through a carbanion intermediate that is protonated faster than it expels basic thiol anions.These results exclude a concerted mechanism for addition-elimination with a concurrent, separate exchange reaction.The solvent kinetic deuterium isotope effect is 3.9 for the addition of thionitrobenzoate dianion to form 3.Buffer catalysis of elimination becomes more significant with more acidic leaving groups and is larger for 3 than for 1 with a given leaving group.The results show that the rate-limiting step changes from addition-elimination of the thiol anion to proton transfer with decreasing pKa of the thiol; the same change is favored by addition of CN to the α-position for a given thiol.The effect of the α-CN group is attributed to conjugation with the developing double bond in the transition state for elimination.The Broensted slope is β = 0.90 for rate-limiting deprotonation of the pentafluorothiophenol adduct 3 and Broensted-type plots against the pKa of the leaving group have slopes of β1g = -0.25 and -0.54 for predominantly rate-limiting deprotonation and leaving group expulsion, respectively.