Specific Process Knowledge/Lithography/EBeamLithography/Cassettes: Difference between revisions
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Revision as of 10:47, 4 March 2024
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Content and illustration by Thomas Pedersen, DTU Nanolab unless otherwise noted.
JEOL 9500 cassette specifications page
General information
Wafer cassettes are available for 2", 4", 6" and 8" wafers. Wafers must be intact, i.e. fractions of wafers can not be exposed in these cassettes. Cassettes dedicated chip exposure are also available. While cassettes are individually adapted to a specific substrate type they naturally share a set of features as illustrated below.
- The front side has six reference planes. One should avoid touching these to preserver them as clean and scratch free as possible.
- One should also avoid touching the hook.
- On the back side each cassettes has a unique ID and barcode. The barcode is read by the cassette transfer system.
- Substrates are held in place by a cover ring that locks with a copper spring clamp. To unlock a cover simply press down on the copper clamp and turn to the open position.
- Most cassettes have a set screw that can be used to precisely rotate the entire substrate slot. This is mostly used for alignment on the pre-aligner.
- Cassettes with a rotation set screw also has a rotation scale.
- Some cassettes have engraved slot ID's
Cassettes are either made in aluminium or titanium. The thermal expansion coefficient of titanium is about one third of that of aluminium. Hence thermal drift is reduced on titanium cassettes.
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Back side (left )and front side view (right) of the 4" wafer titanium cassette (BSPCL-520). |
Stage position and cassette orientation
The stage control window indicates where the stage is currently placed. It indicates this position with a coordinate and a small, red indicator inside the blue box, as illustrated below.
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The stage position is indicated by the red dot inside the blue square. | |
Coordinate system
When placing a substrate in a cassette it is essential to know the relation between the cassette coordinate system and the design coordinate system. On wafer cassettes this is very obvious as they have a flat pin where the flat of the wafer will sit. On chip cassettes the substrate can however be placed at any rotation and hence the exposed pattern can end up upside down if one does not pay attention to this. The pattern coordinate system x' and y' is illustrated below. Notice that the is when the cassette is viewed from the front side with the hook placed to the right.
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Coordinate system is regular orientation when cassette is viewed from the front and hook placed to the right. |
Chip cassette slot dimensions
The slots on chip cassettes are in all cases 70 mm wide. The height of the slots are slot dependent and are:
- 3A: 20 mm
- 3B: 12 mm
- 3C: 8 mm
- 3D: 4 mm
The substrate must overlap at least 0.5 mm on both sides of the slot. Hence the height of a chip must be at least 1 mm larger than the slot height, i.e. in order to use slot 3B the chip height must be at least 13.0 mm.
As the smaller slots are quite narrow and suffer from a significant y-axis offset, it can be necessary to apply an offset for correct placement. The offset indicated below is the observed offset, hence to counter it one must apply a y-axis offset in the opposite direction.
Cassette overview
| Substrate size | ID | Slot ID | Material | Image | Slot center coordinates [µm] | Approximate offset [µm] |
|---|---|---|---|---|---|---|
| Chips | BM4P-509 | 3A, 3B, 3C, 3D | Ti |  |
3A: (80.000, 60.000)
3B: (200.000, 60.000) 3C: (80.000, 180.000) 3D: (200.000, 180.000) |
Measured 2024-01-05
3A: -810 µm 3B: -780 µm 3C: -840 µm 3D: -975 µm |
| Chips | BM4P-510 | 3A, 3B, 3C, 3D | Ti |  |
3A: (80.000, 60.000)
3B: (200.000, 60.000) 3C: (80.000, 180.000) 3D: (200.000, 180.000) | |
| 2" | BM6P-006 | 2A, 2B, 2C, 2D, 2E, 2F | Al |  |
2A: (80.000. 40.000)
2B: (200.000. 40.000) 2C: (80.000. 120.000) 2D: (200.000. 120.000) 2E: (80.000. 200.000) 2F: (200.000. 200.000) | |
| 2" | BM6P-502 | 2A, 2B, 2C, 2D, 2E, 2F | Ti |  |
2A: (80.000. 40.000)
2B: (200.000. 40.000) 2C: (80.000. 120.000) 2D: (200.000. 120.000) 2E: (80.000. 200.000) 2F: (200.000. 200.000) | |
| 3" | BM4P-021 | 3A, 3B, 3C, 3D | Al |  |
3A: (80.000, 60.000)
3B: (200.000, 60.000) 3C: (80.000, 180.000) 3D: (200.000, 180.000) | |
| 3" | BM4P-025 | 3A, 3B, 3C, 3D | Al |  |
3A: (80.000, 60.000)
3B: (200.000, 60.000) 3C: (80.000, 180.000) 3D: (200.000, 180.000) | |
| 4" | BSPCL-520 | 4A, 4B, 4C | Ti |  |
4A: (90.000, 55.000)
4B: (210.000, 55.000) 4C: (150.000, 185.000) | |
| 4" | BM2P-011 | 4D, 4E | Al |  |
4D: (190.000, 65.000)
4E: (100.000, 175.000) | |
| 6" | BW6-009 | 6A | Al |  |
6A: (140.000, 120.000) | |
| 6" | BW6-042 | 6A | Al |  |
6A: (140.000, 120.000) | |
| 8" | BSPCL-514 | 8A | Ti |  |
8A: (189.000, 73.500) | |
| Mask | B6025-025 | Ti |  |
(140.000, 120.000) |