Scanning Electron Microscope

From CleanEnergyWIKI
Jump to navigation Jump to search
The printable version is no longer supported and may have rendering errors. Please update your browser bookmarks and please use the default browser print function instead.
Return to Research Tool Menu

Overview

Sirion sem.png

The scanning electron microscope is used to image the surface of a conducting sample by scanning it with a high energy beam of electrons. The SEM is a useful tool for photonics research because it reveals nano-scale surface features and topography that is critical to the performance of multi-layer devices. SEM produces dramatic pictures that reveal 3D shapes and shadows.

Significance

Some SEMs have additional software enhancements than enable them to focus the beam on a photomask for E-beam lithography or are equipped for focused ion beam (FIB) milling. SEM can be equipped with attachments so it be used for elemental analysis using Energy Disspersive X-ray spectroscopy EDAX.

Operation

Part 1 Tour and Sample Preparation

Part 2 Loading the Sample

Part 3 Setting the Working Distance

Part 4 Lens Alignment and Stigmation

Part 5 Moving the Stage and Imaging

Part 6 Changing the Sample and Shutdown


Energy Dispersive X-ray Spectroscopy

Energy Dispersive X-ray Spectroscopy (EDX is used to determine the composition of a sample such as thin films. Not only can relative amounts of each atom be measured, but the distribution of the atoms in our samples can be mapped.

EDX is an extension of the Sirion Scanning Electron Microscope in the Molecular Analysis Facility, make sure to watch our SEM videos before continuing.

How does EDX determine composition, or, in other words, differentiate between atoms? In general, atoms are composed of nuclei (protons and neutrons) with electrons orbiting around them at different energy levels. During SEM operation, a high-energy electron beam impinges on the sample. Some of these electrons collide with electrons residing at lower energy levels, and both scatter and leave the atom. As a result, an electron located at a higher energy level sees the vacancy and jumps at the opportunity to reside at lower energy level. When the electron moves to this lower energy level, it releases energy – specifically, x-rays. Because these electron transitions are characteristic of the specific element, the energy of these x-ray emissions is also characteristic of the element. You’ll also see that multiple electron transitions for an atom are possible because electrons can fall from different elevated levels.

External Links