MnO2 polymorphs for catalytic carboxylation of 1-butanamine by CO2

N,N'-dibutylurea is an important fine chemical/intermediate with a wide range of applications. Here, the synthesis of N,N '-dibutylurea through catalytic carbonylation of 1-butanamine by CO2 over MnO2 heterogeneous catalysts was systematically investigated. Four polymorphs of MnO2, including alpha-MnO2, beta-MnO2, delta-MnO2 and gamma-MnO2 with various morphological shapes were synthesized by hydrothermal method through altering the synthesis conditions (raw materials or parameters). Significant impact of the lattice structure of the MnO2 oxides on the catalytic activity was demonstrated. Among them, delta-MnO2 possessed the most favorable catalytic activity with N,N '-dibutylurea yield as high as 85.78 % at 160 degrees C for 24 h in CO2, while it is only 76.70 % for the alpha-MnO2, although they showed the similar specific surface area of around 10 m(2) g(-1). To understand the different catalytic behaviors among the different structured MnO2, the catalysts were characterized by X-ray photoelectron spectroscopy and temperature-programmed desorption of CO2. It was discovered that the excellent performance of delta-MnO2 was ascribed to its high surface basicity from its high concentration of lattice oxygen on surface of MnO2, while the large amount of surface unsaturated coordination manganese also positively affected the catalytic performance of gamma-MnO2. It suggests enhancement of surface basicity and defect concentration is critical for the development of superior MnO2-based catalysts for the green synthesis of N,N '-dibutylurea from catalytic carbonylation of 1-butanamine by CO2.

Automated summary

The study investigated the catalytic carbonylation of 1-butanamine by CO2 over MnO2 heterogeneous catalysts and found that the lattice structure of MnO2 oxides significantly impacts the catalytic activity. Among the four polymorphs of MnO2, delta-MnO2 showed the most favorable catalytic activity due to its high surface basicity from the concentration of lattice oxygen on its surface. Enhancing surface basicity and defect concentration are crucial for developing superior MnO2-based catalysts for the green synthesis of N,N'-dibutylurea.