### Session L1: Focus Session: Imaging and Modifying Materials at the Limits of Space and Time Resolution

2:30 PM–5:30 PM, Tuesday, February 28, 2012
Room: 203

Chair: Bernd Kabius, Pacific Northwest National Laboratory

Abstract ID: BAPS.2012.MAR.L1.1

### Abstract: L1.00001 : In-Situ Transmission Electron Microscopy with Nanosecond Temporal Resolution

2:30 PM–3:06 PM

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#### Author:

Nigel Browning
(Pacific Northwest National Laboratory)

The dynamic transmission electron microscope (DTEM) can obtain both high spatial ($\sim$1nm or better) and high temporal ($\sim$1$\mu$s or faster) resolution. The high temporal resolution is achieved by using a short pulse laser to create the pulse of electrons through photo-emission. This pulse of electrons is propagated down the microscope column in the same way as in a conventional high-resolution TEM. The only difference is that the spatial resolution is limited by the electron-electron interactions in the pulse (a typical 10ns pulse contains $\sim$10$^{9}$ electrons). To synchronize this pulse of electrons with a particular dynamic event, a second laser is used to drive'' the sample a defined time interval prior to the arrival of the laser pulse. The important aspect of the DTEM is that one pulse of electrons is used to form the whole image, allowing irreversible transitions and cumulative phenomena such as nucleation and growth, to be studied directly in the microscope. The use of the drive laser for fast heating of the specimen presents differences and several advantages over conventional resistive heating \textit{in-situ} TEM -- such as the ability to drive the sample into non-equilibrium states. So far, the drive laser has been used for \textit{in-situ} processing of nanoscale materials, rapid and high temperature phase transformations, and controlled thermal activation of materials. In this presentation, a summary of the development of the DTEM and in-situ stages to control the environment around the specimen will be described. Particular attention will be paid to the potential for gas stages to study catalytic processes and liquid stages to study biological specimens in their live hydrated states. The future potential improvements in spatial and temporal resolution that can be expected through the implementation of upgrades to the lasers, electron optics and detectors will also be discussed.

To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2012.MAR.L1.1