Specific Process Knowledge/Characterization/Sample imaging: Difference between revisions
No edit summary |
|||
| Line 10: | Line 10: | ||
Using the different options such as bright/dark field, polarizer or transmitted/reflected light one can find a better signal for a specific need. Some of them have a camera that allows you to capture and store images. | Using the different options such as bright/dark field, polarizer or transmitted/reflected light one can find a better signal for a specific need. Some of them have a camera that allows you to capture and store images. | ||
One of the advantages of the optical microscopes is that they provide fast and easy accessible information about any sample without any kind of sample preparation. They do, however, also have some limitations. | One of the advantages of the optical microscopes is that they provide fast and easy accessible information about any sample without any kind of sample preparation. They do, however, also have some limitations. Since the depth of focus is quite limited, especially at high magnifications, one will experience problems when trying to image strucutures that have been etched more than some 10 µm: One cannot focus on both the top and the bottom at the same time. Another disadvantage is the physical limit to the resolution that makes it impossible to image structures below 1 µm. | ||
Both shortcomings of the microscopes mentioned above are addressed if you use a SEM instead. The depth of focus and the resolution of a SEM are at least one order better. | |||
Revision as of 12:06, 24 January 2008
The list of instruments for sample imaging available at Danchip includes 6 optical microscopes , three scanning electron microscopes (SEM's) and an atomic force microscope (AFM). These instruments cover a wide range of applications.
What kind of instrument to use
There is a lot of optical microscopes scattered around in the cleanroom because they are in great need. They are useful if, for instance, you need to
- inspect the quality of UV exposed photoresist when doing photolithography,
- check for particles on wafers that have been processed in the furnaces or the PECVD's,
- check the quality of KOH etched structures or
- generally verify any in batch process.
Using the different options such as bright/dark field, polarizer or transmitted/reflected light one can find a better signal for a specific need. Some of them have a camera that allows you to capture and store images.
One of the advantages of the optical microscopes is that they provide fast and easy accessible information about any sample without any kind of sample preparation. They do, however, also have some limitations. Since the depth of focus is quite limited, especially at high magnifications, one will experience problems when trying to image strucutures that have been etched more than some 10 µm: One cannot focus on both the top and the bottom at the same time. Another disadvantage is the physical limit to the resolution that makes it impossible to image structures below 1 µm.
Both shortcomings of the microscopes mentioned above are addressed if you use a SEM instead. The depth of focus and the resolution of a SEM are at least one order better.
| Optical microscopes | SEM | AFM | |
|---|---|---|---|
| Magnification range | 25x to 1000x | 100x to 500.000x | Maximum scanned area 90x90 µm |
| Depth of focus | Low | Very high |