Facile Manner in Regulating the Graphene-Shelled Structure of Cobalt Nanoparticles for the Synthesis of Amines

The synthesis of pharmaceutical relevant compounds keeps close ties with the development of metalbased catalysts, which remains a common goal in chemical research to solve challenges of application, such as the deactivation of catalyst caused by its tender structure or metal leaching. In this work, we reported a simple and manageable method for the preparation of heterogeneous catalyst with stable cobalt nanoparticles that encapsulated by the outer graphitic shell, whose catalytic activity and selectivity for the synthesis of primary amines via a wide range of aldehydes (more than 52 examples), ketones (more than 26 examples), and nitriles (more than 18 examples) were proved to be broadly effective (but not all of them are shown). And also, subsequent synthesis of N, N-dimethylamine compounds following a brand-new tandem pot process by the same Co-based catalyst were simultaneously explored. In most cases, the Co-based catalyst enables easy substitution of –NH2 moiety towards functionalized and structurally diverse molecules under very mild industrially viable and scalable conditions, providing cost-effective access to numerous amines and other precursors for more complex drug products. More surprisingly, the Co-based catalyst can also be easily recycled due to its intrinsic magnetism and still remains excellent catalytic activity and selectivity for the target products even after reusing up to twelve times. Results from analytic technologies, including but not limited to XRD, XPS, TEM/Mapping and in-suit FTIR, reveals that the structural features of catalyst are closely in relation to its catalytic mechanisms; in simple terms, the outer graphitic shell is activated by the electronic interactions between the inner metallic nanoparticles and the carbon layer as well as the induced charge redistribution. Except for the gram-scale batch test in laboratory, we have firstly evaluated the lifecycle of Co-based catalyst on an automatic hydrogenation reactor by employing continuous flows of reactant (5 ml/min, react within 1.6 min) under the similar conditions (90 °C, 3 MPa H2, 0.1 mol/L), whose results suggests the theoretically minimal lifecycle of Co-based catalyst can reach a continuous period of 72 h without any significant loss of catalytic efficiency. In conclusion, the advantages of this newly developed method involving operational simplicity, high stability, easily recyclable, cost-effective of the catalyst, and good functional group compatibility for the synthesis of functional amines, as well as the highly efficient and industrial applicable tandem synthesis process. <br>

Facile Manner in Regulating the Graphene-Shelled Structure of Cobalt Nanoparticles for the Synthesis of Amines

The synthesis of pharmaceutical relevant compounds keeps close ties with the development of metalbased catalysts, which remains a common goal in chemical research to solve challenges of application, such as the deactivation of catalyst caused by its tender structure or metal leaching. In this work, we reported a simple and manageable method for the preparation of heterogeneous catalyst with stable cobalt nanoparticles that encapsulated by the outer graphitic shell, whose catalytic activity and selectivity for the synthesis of primary amines via a wide range of aldehydes (more than 52 examples), ketones (more than 26 examples), and nitriles (more than 18 examples) were proved to be broadly effective (but not all of them are shown). And also, subsequent synthesis of N, N-dimethylamine compounds following a brand-new tandem pot process by the same Co-based catalyst were simultaneously explored. In most cases, the Co-based catalyst enables easy substitution of –NH2 moiety towards functionalized and structurally diverse molecules under very mild industrially viable and scalable conditions, providing cost-effective access to numerous amines and other precursors for more complex drug products. More surprisingly, the Co-based catalyst can also be easily recycled due to its intrinsic magnetism and still remains excellent catalytic activity and selectivity for the target products even after reusing up to twelve times. Results from analytic technologies, including but not limited to XRD, XPS, TEM/Mapping and in-suit FTIR, reveals that the structural features of catalyst are closely in relation to its catalytic mechanisms; in simple terms, the outer graphitic shell is activated by the electronic interactions between the inner metallic nanoparticles and the carbon layer as well as the induced charge redistribution. Except for the gram-scale batch test in laboratory, we have firstly evaluated the lifecycle of Co-based catalyst on an automatic hydrogenation reactor by employing continuous flows of reactant (5 ml/min, react within 1.6 min) under the similar conditions (90 °C, 3 MPa H2, 0.1 mol/L), whose results suggests the theoretically minimal lifecycle of Co-based catalyst can reach a continuous period of 72 h without any significant loss of catalytic efficiency. In conclusion, the advantages of this newly developed method involving operational simplicity, high stability, easily recyclable, cost-effective of the catalyst, and good functional group compatibility for the synthesis of functional amines, as well as the highly efficient and industrial applicable tandem synthesis process. <br>

Nanocomposite Synthesis of Nanodiamond and Molybdenum Disulfide

A chemically conjugated nanodiamond (ND)/MoS2 nanocomposite was synthesized with amine-functionalized MoS2 and acyl chloride-coordinated ND. The chemical structure and morphology of the nanocomposite were characterized to examine the dispersion of MoS2 on the ND platform. The results revealed that the degree of dispersion was enhanced with increasing ratio of MoS2 nanosheets to ND. Moreover, the nanosheets consisted of several molecular interlayers that were well-dispersed on the ND platform, thereby forming a nanophase. The efficient electrocapacity of the ND/MoS2 nanocomposite was considerably greater than that of the MoS2 electrode alone. Furthermore, the nanophase distribution of MoS2 on ND with a graphitic shell provided a large surface area and reduced the diffusion distance of ions and electrons. Therefore, the nanophase electrode showed higher electrochemical capacitance than that of the MoS2 electrode alone.

Highly stable mesoporous silica nanospheres embedded with FeCo/graphitic shell nanocrystals as magnetically recyclable multifunctional adsorbents for wastewater treatment

We report the first synthesis of highly stable and efficiently recyclable multifunctional adsorbents containing FeCo/GC nanoparticles with the strongest magnetic properties.