AbstractsChemistry

Micro-Structure of Functional Particles and Particle Systems

by Mao Deng




Institution: Christian-Albrechts-Universität zu Kiel
Department:
Year: 2015
Posted: 02/05/2017
Record ID: 2134660
Full text PDF: http://macau.uni-kiel.de/receive/dissertation_diss_00017267


Abstract

Nanoparticles and particle systems exhibit exceptional properties in various applications. In the present dissertation the results of the transmission electron microscopy (TEM) analysis in microstructures of nanoparticles and of hybrid nanocomposites with different length scales are presented. The functional particles and particle systems under study include samples from: 1. MoS2 based catalysts and their composites. A photocatalyst MoS2/carbon/phosphorus composite is synthesized, and high resolution TEM (HRTEM) visualizes the expanded (002) lattice planes. Electron energy loss spectroscopy (EELS) results suggest an ordered and sp2 bonding dominated carbon species. In situ electron beam irradiation shows instability of the composite sample. The intercalation of graphitic carbon inside the 250 °C sample and the nanoslabs with more active sites in the 350 °C sample are responsible for their higher photocatalytic activities as compared to bulk MoS2. With regard to an amorphous MoS2 (PX) sample, in situ electron beam irradiation and in situ thermal annealing inside TEM both lead to an increased crystallinity. Yet statistic studies comparing the size distribution of the MoS2 slabs reveal different crystallization mechanisms of the two pathways. The inherent coordinatively unsaturated sites inside the PX sample account for the high photocatalytic activity. In hydrodesulferizaton (HDS) catalysts where PX is promoted with cobalt, HRTEM reveals microstructural difference between samples prepared under different conditions, and their HDS catalytic activity is related accordingly. Quantitative analyses of electron diffraction show a good agreement with size distributions of MoS2 nanoparticles. Kinematic and dynamic simulations of a diffraction pattern reveal the influence of HDS reaction on crystallinity and microstructure of MoS2 phase. Computer simulation of the interface between MoS2 and Co is performed for understanding promoter effect. For MoS2/carbon composite as a potential candidate for catalyst and electrode, EELS analyses suggest a mixture of graphitic and carbide-like carbons. Synthesis conditions play an important role on the structure of the sample. 2. Quasi 1D MoO3, SnO2 nanorods and core-shell composite. For the MoO3 nanorods, TEM structural and compositional studies reveal the growth direction and the highly defective structure of the orthorhombic MoO3. The performance of the MoO3 nanorods sensor toward ethanol vapor is related to the surface catalytic reaction on the lattice oxygen of MoO3. The reaction is further facilitated by the defect rearrangement of the crystallographic structure. The fast gas response is due to the dimension of the MoO3 nanorods. For the SnO2/Ga2O3/GaN:Ox composite, a comprehensive approach of energy filtered TEM, diffraction, HRTEM and in situ heating is applied to reveal the complex structure of the sample. The influences of thermal annealing to the structure are demonstrated via ex situ and in situ heating experiments. 3. Carbon microtube (Aerographite, AG) and its variants.…