Dr. Yuanyuan Zhu

Staff Scientist at the Energy and Environment Directorate at Pacific Northwest National Laboratory

Monday, February 19, 2018

Institute of Materials Science Building, Room 159, at 9:45 a.m.  

Refreshments served at 9:30 a.m.

“Making Room at the Bottom with Advanced Scanning Transmission Electron Microscopy”

Abstract: In his famous lecture in 1959, Richard Feynman stated, “it would be very easy to make an analysis of any complicated chemical substance, all one would have to do would be to LOOK AT it and see where the ATOMS are.” In this talk, I will show how can we leverage the advanced scanning transmission electron microscopy (STEM) to accelerate the innovations in heterogeneous functional nanomaterials at the fundamental atomistic scale.

Modifying nanoscale materials by trace amounts of foreign elements represents an opportunity to extend their unique functionalities. Currently, much interest is devoted to the functional promotion of layered dichalcogenides, such as MoS2, for diverse applications in electronics, optoelectronics and heterogeneous catalysis. To rationally guide the promotional optimization, insight into the location and bonding geometry of the promoter elements is needed at the level of a single atom. I will show how we combine low-voltage and low-dose aberration-corrected STEM with electron energy loss spectroscopy (EELS) to enable the first single-atom sensitive spectroscopic analysis that unambiguously identifies single Co atoms in a promoted industrial-style MoS2 nanocatalyst in its native state. Furthermore, no material is completely static. To truly understand and guide materials design, dynamic behaviors of a functional material system need to be investigated in the presence of corresponding mechanical, electrical, chemical and/or thermal applied fields. Taking gas-solid reaction for instance, it is crucial to understand how the gas molecules affect the scattering of fast electrons contributing to an atomic scale image for better imaging sensitivity and resolvability in reaction relevant gaseous environments. I will show how we evaluated the inelastic-noise-free annular dark-field STEM imaging mode for a directly interpretable observation under the influence of various gaseous environment at different pressure. Using this new environmental STEM (ESTEM), we unambiguously resolved all thirteen cation atomic sites on the surface of a complex oxide catalyst (M1 catalyst) under the working condition. Combining in situ and big-data microscopy approach we revealed a new mechanism of generating catalytic active sites on the surface of a mixed oxide catalyst (M1 catalyst) during oxidative ethane dehydrogenation. This realization opens new perspectives for tailoring nano-oxide functionalities.