Described herein are compositions composed of frustrated Lewis pairs impregnated in porous materials such as, for example, metal-organic frameworks, and their uses thereof. These compositions may allow new applications of frustrated Lewis pairs in catalysis by sequestering and protecting the frustrated Lewis pair within the nanospace of the porous material. Also provided are methods of hydrogenating an organic compound having at least one unsaturated functional group comprising using the compositions described herein.

A dibromobenzyl derivative with a structure shown as formula I, a stereoisomer or a pharmaceutically acceptable salt thereof and a preparation method and an application of the dibromobenzyl derivative are provided. The dibromobenzyl derivative or the stereoisomer thereof is superior in in-vivo pharmacokinetic stability and drug efficacy, and capable of being used for preparing respiratory drugs, in particular the apophlegmatic drugs.

##STR00001##

A dibromobenzyl derivative with a structure shown as formula I, a stereoisomer or a pharmaceutically acceptable salt thereof and a preparation method and an application of the dibromobenzyl derivative are provided. The dibromobenzyl derivative or the stereoisomer thereof is superior in in-vivo pharmacokinetic stability and drug efficacy, and capable of being used for preparing respiratory drugs, in particular the apophlegmatic drugs.

##STR00001##

The present disclosure relates to a method for preparing isophorone diamine by means of a hydrogenation reduction of isophorone nitrile imine. The hydrogenation reduction is continuously carried out in a multi-stage bubble column reactor loaded with a supported alkaline cobalt-based catalyst, wherein isophorone nitrile imine is successively in countercurrent contact with hydrogen in each stage of the reactor to carry out a hydrogenation reduction reaction, so as to obtain the isophorone diamine. The preparation method solves the problem of back-mixing, and further improves the conversion rate and the cis/trans ratio of the product.

The present disclosure relates to a method for preparing isophorone diamine by means of a hydrogenation reduction of isophorone nitrile imine. The hydrogenation reduction is continuously carried out in a multi-stage bubble column reactor loaded with a supported alkaline cobalt-based catalyst, wherein isophorone nitrile imine is successively in countercurrent contact with hydrogen in each stage of the reactor to carry out a hydrogenation reduction reaction, so as to obtain the isophorone diamine. The preparation method solves the problem of back-mixing, and further improves the conversion rate and the cis/trans ratio of the product.

The application relates to a strongly-polarized molecule of the following general formula: wherein A denotes a group having a polarizability greater than 2 C.Math.m.sup.2/V; R.sub.1 and R.sub.2 are respectively hydrogen, halogen, a hydroxyl group, an amino group, a cyano group, a nitro group, a carboxyl group, a C.sub.1-12 alkyl group, a C.sub.1-12 alkoxy group, a halogenated C.sub.1-12 alkyl group, a halogenated C.sub.1-12 alkoxy group, a hydroxyl C.sub.1-12 alkyl group, a hydroxyl C.sub.1-12 alkoxy group, or a C.sub.1-12 alkyl amino group; x.sub.1 and x.sub.2 denote 0 or an integer no less than 1, respectively; and y.sub.1 and y.sub.2 denote 0 or an integer no less than 1, respectively. The application further relates to a strongly-polarized molecule-graphene molecule heterojunction, and a single molecule field effect transistor comprising a substrate, a gate, a dielectric layer and the strongly-polarized molecule-graphene molecule heterojunction; and the dielectric layer is located between the gate and the strongly-polarized molecule-graphene molecule heterojuction. The single molecule field effect transistor provided by the application can realize highly-efficient gate modulation.

##STR00001##

The present disclosure provides methods for making quinolinyldiamine products from quinolinyl starting materials. In addition, the quinolinyldiamines can be used as ligands or ligand precursors for catalysts, e.g. for use in olefin polymerization.

The present disclosure provides methods for making quinolinyldiamine products from quinolinyl starting materials. In addition, the quinolinyldiamines can be used as ligands or ligand precursors for catalysts, e.g. for use in olefin polymerization.

Methods of making antidegradant compounds are disclosed in which a p-phenylenediamine is reacted with a dicarbonyl to thereby obtain a diimine, which is reduced to obtain mixtures comprising the antidegradant compound.

Methods of making antidegradant compounds are disclosed in which a p-phenylenediamine is reacted with a dicarbonyl to thereby obtain a diimine, which is reduced to obtain mixtures comprising the antidegradant compound.