The thermal decomposition of ammonia borane was studied using a variety of methods to qualitatively identify gas and remnant solid phase species after thermal treatments up to 1500 °C. At about 110 °C, ammonia borane begins to decompose yielding H(2) as the major gas phase product. A two step decomposition process leading to a polymeric -[NH═BH](n)- species above 130 °C is generally accepted. In this comprehensive study of decomposition pathways, we confirm the first two decomposition steps and identify a third process initiating at 1170 °C which leads to a semicrystalline hexagonal phase boron nitride. Thermogravimetric analysis (TGA) was used to identify the onset of the third step. Temperature programmed desorption-mass spectroscopy (TPD-MS) and vacuum line methods identify molecular aminoborane (H(2)N═BH(2)) as a species that can be released in appreciable quantities with the other major impurity, borazine. Attenuated total reflectance Fourier transform infrared spectroscopy (ATR-FTIR) was used to identify the chemical states present in the solid phase material after each stage of decomposition. The boron nitride product was examined for composition, structure, and morphology using scanning Auger microscopy (SAM), powder X-ray diffraction (XRD), and field emission scanning electron microscopy (FESEM). Thermogravimetric Analysis-Mass Spectroscopy (TGA-MS) and Differential Scanning Calorimetry (DSC) were used to identify the onset temperature of the first two mass loss events.
Molecular adsorption and oxidation at manganese oxide/liquid interfaces has attracted increased interest due to its importance in the development of heterogeneous catalysts, microbial fuel cells, and selective adsorption materials. Here we report the adsorption and oxidation of phenolic compounds on Cu2+, Co3+, and Ce4+ doped K−OMS-2 nanofibers. Different metal ion doped K−OMS-2 catalysts show distinct adsorption and oxidation ability. The structure and compositions of doped K−OMS-2 catalysts were characterized by X-ray diffraction and atomic absorption analyses. The relationships of catalyst structure-catalytic properties were discussed. The adsorbed polymeric nanospheres on doped K−OMS-2 nanofibers were investigated by field emission scanning electron microscopy, Fourier transform infared spectroscopy, transmission electron microscopy, and energy dispersive X-ray analyses. These nanospheres were totally oxidized to CO2 in oxygen or air at 553−603 K catalyzed by doped and undoped K−OMS-2 itself. OMS-2 was regenerated with air or oxygen. The chemisorption and oxidation of phenol in an anaerobic environment (N2) demonstrate that lattice oxygen of cryptomelane is involved in these processes. Free-radical mechanisms are proposed for the oxidation of phenol in O2 and for the formation of phenolic nanospheres. Compared with undoped K−OMS-2, metal ion doped K−OMS-2 shows higher adsorption capacity of phenolic compounds and higher phenol removal rate.
The
development of catalysts with high thermal stability is receiving
considerable attention. Here, we report manganese oxide octahedral
molecular sieve (OMS-2) materials with remarkably high thermal stability,
synthesized by a simple one-pot synthesis in a neutral medium. The
high thermal stability was confirmed by the retention of the cryptomelane
phase at 750 °C in air. Mechanistic studies were performed by
X-ray absorption near-edge structure (XANES) spectroscopy and ex situ X-ray diffraction (XRD) to monitor the change in
oxidation state and the phase evolution during the thermal transformation.
These two techniques revealed the intermediate phases formed during
the nucleation and growth of highly crystalline cryptomelane manganese
oxide. Thermogravimetric analysis, Fourier transform infrared spectroscopy
(FTIR), time-dependent studies of field emission scanning electron
microscopy (FE-SEM), and high-resolution transmission electron microscopy
(HR-TEM) techniques confirm the formation of these intermediates.
The amorphous phase of manganese oxide with random nanocrystalline
orientation undergoes destructive reformation to form a mixture of
birnessite and hausmannite during its thermal transformation to pure
crystalline OMS-2. The material still has a relatively high surface
area (80 m2/g) even after calcination to 750 °C. The
surfactant was used as a capping agent to confine the growth of OMS-2
to form short nanorods. In the absence of the surfactant, the OMS-2
extends its growth in the c direction to form nanofibers.
The particle sizes of OMS-2 can be controlled by the temperatures
of calcination. The OMS-2 calcined at elevated temperatures (400–750
°C) shows high remarkable catalytic activity for oxygen reduction
reaction (ORR) in aqueous alkaline solution that outperformed the
activity of synthesized solvent-free OMS-2. The activity follows this
order: OMS-2500 °C > OMS-2750 °C > OMS-2400 °C. The developed method reported
here can be easily scaled up for synthesis of OMS-2 for use in high-temperature
(400–750 °C) industrial applications, e.g., oxidative
dehydrogenation of hydrocarbons and CO oxidation.
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