Toward a New Era of Electron Microscopy: Imaging electron charge distribution and atomic vibration with atomic resolution
时间:2019年3月19日(星期二),上午10:00
地点:浙江大学玉泉校区曹光彪大楼324
报告人:潘晓晴教授
邀请人:张泽院士
报告人简介:Xiaoqing Pan is the Henry Samueli Endowed Chair in Engineering, and Professor of Chemical Engineering & Materials Science, Professor of Physics & Astronomy at the University of California-Irvine (UCI). He is also the inaugural Director of the Irvine Materials Research Institute (IMRI) at UCI.Pan's research interests center on the development of atomic resolution transmission electron microscopy (TEM) and in situ techniques, leading understanding of the atomic-scale structure-property relationships of advanced functional materials. He has published over 400 peer-reviewed scientific papers in scholarly high impact factor journals. His work has been cited over 20,000 times and his h-factor is 76 (Google Scholar). He has given more than 250 plenary, keynote or invited presentations at national and international conferences, and more than 200 invited seminars in national and international institutions.
报告摘要:The development of aberration corrector and monochromator for transmission electron microscope (TEM) marked the great milestones, and the availability of direct electron detector and high-performance spectrometer unlocked a door for a new era of discovery in materials research. Today, the advanced TEM enables the measurements of 3D atomic structure, composition, chemical bonding, and local electronic properties of materials with the atomic resolution. It was recently shown that, by coupling a high-speed pixelated electron detector with an aberration corrected scanning transmission electron microscope (STEM), electric field mapping can be obtained using scanning diffraction or four-dimensional (4D) STEM. We developed a real space imaging technique to map the local charge density with the sub-Å spatial resolution. By analyzing the local total charge surrounding an atom, we show the charge state can be measured at the level of single atomic column.