Electro-transformation

O., David, E, and Leblon, G. (1990) Interspecies electro-transformation in Corynebacteria. FEMS Microbiol Lett., 54 (1-3), 263-269. 

Haynes, J.A. and Britz, M.L. (1989) Electro transformation of Brevibacterium lactofermentum and Corynebacterium glutamicum. growth in tween 80 increases transformation frequencies. FEMS Microbiol Lett, 61 (3 329-334. 

Xue, G.-P., Johnson, J.S, and Dalrymple, B.P. (1999) High osmolarity improves the electro-transformation efficiency of the gram-positive bacteria Bacillus subtilis and Bacillus licheni-formis. J. Microbiol Methods, 34 (3), 183-191. 

Cao, G. et al. (2011) A modified electro-transformation method for Bacillus subtilis and its application in the production of antimicrobial lipopeptides. Biotechnol Lett, 33 (5), 1047-1051. 

Lu, Y.P. et al (2012) Study on the electro-transformation conditions of improving transformation efficiency for Bacillus subtilis. Lett. Appl. Microbiol, 55 (1), 9-14. 

The seminal discovery that transformed membrane separation from a laboratory to an industrial process was the development, in the early 1960s, of the Loeb-Sourirajan process for making defect-free, high flux, asymmetric reverse osmosis membranes (5). These membranes consist of an ultrathin, selective surface film on a microporous support, which provides the mechanical strength. The flux of the first Loeb-Sourirajan reverse osmosis membrane was 10 times higher than that of any membrane then avaUable and made reverse osmosis practical. The work of Loeb and Sourirajan, and the timely infusion of large sums of research doUars from the U.S. Department of Interior, Office of Saline Water (OSW), resulted in the commercialization of reverse osmosis (qv) and was a primary factor in the development of ultrafiltration (qv) and microfiltration. The development of electro dialysis was also aided by OSW funding. 

The correctness of this statement is to be inferred from the exact agreement between the values of the mechanical equivalent of heat obtained by different methods. Thus, in Joule s second series of experiments, mechanical work is directly converted into heat in the first and third series, it is indirectly transformed through the medium of electro-magnetic energy in the fourth series, the energy of an electric current is converted into heat the identity of the values of J so obtained implies a complete conversion of the initial forms of energy into heat energy. 

Chemical reactivity of unfunctionalized organosilicon compounds, the tetraalkylsilanes, are generally very low. There has been virtually no method for the selective transformation of unfunctionalized tetraalkylsilanes into other compounds under mild conditions. The electrochemical reactivity of tetraalkylsilanes is also very low. Kochi et al. have reported the oxidation potentials of tetraalkyl group-14-metal compounds determined by cyclic voltammetry [2]. The oxidation potential (Ep) increases in the order of Pb < Sn < Ge < Si as shown in Table 1. The order of the oxidation potential is the same as that of the ionization potentials and the steric effect of the alkyl group is very small. Therefore, the electron transfer is suggested as proceeding by an outer-sphere process. However, it seems to be difficult to oxidize tetraalkylsilanes electro-chemically in a practical sense because the oxidation potentials are outside the electrochemical windows of the usual supporting electrolyte/solvent systems (>2.5 V). 

The thermodynamic stabilities of phenonium ions have been determined based on bromide-transfer equilibria in the gas phase and, depending on the substituents, the bridged species (1) has been proposed as an intermediate or transition state on the potential-energy surface for the 1,2-aryl rearrangement of triarylvinyl cations (see Scheme 1). Phenonium ion (3) has been presented as an intermediate to account for the fact that lactonization of methyl 4-aryl-5-tosyloxy hexanoate (2) produces y-lactone (4) selectively under thermodynamic conditions, but affords 5-lactone (5) preferentially under kinetic conditions. It has been shown that anodic oxidation of frany-stilbene in alcohols in the presence of KF or BU4NBF4 is accompanied by its electro-oxidative rearrangement into diphenylacetaldehyde acetals. The mechanism outlined in Scheme 2 has been proposed" for the transformation. 

Hydrogen is a secondary fuel and, like electricity, is an energy carrier. It is the most electroactive fuel for fuel cells operating at low and intermediate temperatures. Methanol and ethanol are the most electroactive alcohol fuels, and, when they are electro-oxidized directly at the fuel cell anode (instead of being transformed in a hydrogen-rich gas in a fuel processor), the fuel cell is called a DAFC either a DMFC (with methanol) or a DEFC (with ethanol). 

We also discovered the ability of 2-azadienes of this sort to cycloadd to unactivated carbon—carbon double and triple bonds in an intramolecular fashion (89CC267) (Scheme 50) such a process appears to be one of the first examples of intramolecular [4 + 2] cycloadditions of simple 2-azadienes. Azadiene 216 was made from O-allyl salicylaldehyde 215 (R = allyl) and heated at 120°C in toluene to furnish the trans-fused tricyclic adduct 217 in excellent yield further dehydrogenation of 217 with DDQ afforded 5H-[ 1 ]-benzopyran[4,3-6]pyridine 218. On the other hand, when 0-(2-butynyl) salicylaldehyde 215 (R = 2-butynyl) was transformed into azadiene 219 and subjected to heating in a sealed tube at 150°C, pyridine 222 was isolated in very high yield. Its formation can be rationalized to occur via the expected Diels-Alder intermediate 220 thus, [1,5]-H shift in 220 would give rise to tautomer 221, which would suffer electro-cyclic ring-opening and aromatization to pyridine derivative 222. 

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