In situ FT-IR spectroelectrochemical study of the reduction of 1,4-DINITROBENZENE (cas 100-25-4) in room-temperature ionic liquids
-
Add time:07/19/2019 Source:sciencedirect.com
The electrochemical reduction of 1,4-DINITROBENZENE (cas 100-25-4) (PNB) in ionic liquid (BMIMPF6 and HMIMPF6) has been studied by cyclic voltammetry (CV) and IR spectroelectrochemistry. In ionic liquid, only one couple of redox peak is observed, but the results obtained from IR spectroelectrochemistry support the existence of intermediate (PNB−) in ionic liquid, hence it is reduced in two-step one-electron transfer. The results obtained in mixed media (CH3CN with ionic liquids) suggest that the electrochemical products (radical anion PNB− and dianion PNB2 −) can form strong ion-pairing with the cation of ionic liquid, and the interaction between the electrochemical products and BMIM+ is much stronger than HMIM+. In proton donors mixed media (ionic liquid with ethanol), the interaction of hydrogen-bonding between the electrochemical products and ethanol is much stronger than the interaction of ion-pairing between the electrochemical products and the cation of ionic liquid.
We also recommend Trading Suppliers and Manufacturers of 1,4-DINITROBENZENE (cas 100-25-4). Pls Click Website Link as below: cas 100-25-4 suppliers
Prev:Experimental and theoretical study of the structure of N,N-DIMETHYL-4-NITROANILINE (cas 100-23-2) derivatives as model compounds for non-linear optical organic materials
Next:FT-IR spectroelectrochemical study of the reduction of 1,4-DINITROBENZENE (cas 100-25-4) on Au electrode: Hydrogen bonding and protonation in proton donor mixed media) - 【Back】【Close 】【Print】【Add to favorite 】
- Related Information
- Vibrational spectra and structure of 1,4-DINITROBENZENE (cas 100-25-4) and its 15N labelled derivatives: an ab initio and experimental study07/20/2019
- FT-IR spectroelectrochemical study of the reduction of 1,4-DINITROBENZENE (cas 100-25-4) on Au electrode: Hydrogen bonding and protonation in proton donor mixed media07/21/2019