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Overview
Birck supplies a selection of photoresists for both optical and electron beam lithography. Resists that are not supplied may be purchased for use by individual research groups. The chemical mechanism for each resist may be slightly different, so be sure to verify the appropriate process for each resist.
Optical Lithography:
BNC Supplied:
- AZ1518: Positive photoresist, thicknesses from 1-4 μm
- AZ9260: Positive photoresist, thicknesses from 5-20 μm
Used at facility (not supplied):
- SU-8: Positive Negative epoxy resist
Electron Beam Lithography:
BNC Supplied:
- 950 PMMA A4: Positive resist, BNC supplies:
- 950: A2, A4, A6, A8, A10
495: A2, A4
- XR1541 (HSQ): Negative resist
Optical Photoresists
General Properties of AZ/Ti Photoresists
AZ1518
Used at facility (not supplied):
- ZEP520A: Positive resist.
Optical Photoresists
Composition
The AZ positive resists consist of a resin (Novolak), a photoactive compound or PAC (a DNQ compound), and a solvent (PGMEA).
General Properties of AZ/Ti Photoresists
AZ1518
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BNC supplied photoresist |
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Properties: AZ1518 is optimized for adhesion and stability in wet etching. It has broad photosensitivity from 310-440 nm, a minimum resolution of 0.8-1.2 µm, and is optimized for thicknesses of 1.5-3 µm (films thicker than 3 µm may begin to show "bubbles", a result of the nitrogen released during exposure that cannot escape the top of the film). It has a softening point at 110 °C, and will begin to formed rounded structures at and beyond this temperature. Beyond 120 °C, the resist will react with oxygen, become brownish, and cracks will begin to form. At 170-180 °C, the resist will crosslink. It is stable in HF/BOE and other acids, though strong acids (Sulfuric, Nitric) and bases will dissolve it. Dry etching performance will be limited by the thermal stability and rounding temperature. Process: Starting from a clean, hydrophobic substrate surface, the resist should be processed:
PGMEA (as AZ EBR Solvent or another brand name) can be used for edge bead removal or dilution. References: |
AZ9260
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BNC supplied photoresist |
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For thick (>5 µm) films of AZ9260, the required exposure time will depend on the photoresist thickness. References: |
AZ 5214
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Not BNC supplied, must be purchased by individual research groups |
LOR3B
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Per Microchem: Ensure that acetone and resist waste are kept separate from LOR/PMGI waste streams. LOR/PMGI will precipitate in the presence of acetone, PGMEA, and ethyl lactate and may clog lines or form unwanted solids in the collection area. |
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Not BNC supplied, must be purchased by individual research groups |
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LOR3B is a mixture of the solvents Cyclopentanone and 1-Methoxy-2-propanol, with a 'Polyaliphatic imide copolymer' as the polymer. Edge beads can be removed with EBR PG, and it can be lifted off with Remover PG. References: |
Electron Beam Photoresists
950 PMMA A4
Properties
PMMA
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BNC supplied photoresist |
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BNC supplies a variety of PMMA blends. The PMMA specification (e.g. 950 PMMA A4) indicates that the average molecular weight of the dissolved molecules (950 = 950,000 mw, 495 = 495,000 mw). The "A" indicates anisole is the primary solvent, which replaced older chlorobenzene blends. The number after the A indicates the weight percentage of polymethylmethacrylate dissolved. Currently stocked varieties:
Properties
Manufacturer recommended process |
(summarized from Microchem PMMA Data Sheet)
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Sensitivity of PMMA depends on the concentration, developer used, and accelerating voltage of the exposure (e.g. Rooks 2002) . At 100 kV for our PMMA, developed in 1:3 MIBK/IPA, 700 μC/cm2 may be a good dose for 2D features (Hoole 1997), with small isolated lines requiring a dose >3000 μC/cm2 . PMMA References:
PMMA Processes/Common IssuesBurning/Bubbling in evaporators PMMA burning/bubbling may be seen in metallization, particularly the E-beam evaporators. This is seen commonly as a result of insufficient pre-bake of the spun PMMA film before exposure. The recommended is 180 C for 60-90 s. If it's below that temperature, insufficient pre-bake temperature is likely the issue. If you're already baking at that temperature and time, it may be an issue with placement on the hotplate or poor contact. If it's neither of those, it could be thermals in the machine, as PMMA is further crosslinked in the evaporators due to X-rays. However, this would likely be more of a cracking than burning. If the sample was properly baked and thermal contact is good, it may be an issue with the evaporator. A crack in the crucible can cause thermal shorting. Mechanisms
Cold Development
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XR1541 (HSQ)
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BNC Supplied photoresist, but HSQ is very different from other photoresists. Talk to Justin Wirth or Bill Rowe before using! |
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Hydrogen silsesquioxane is a spin on glass that crosslinks with exposure to e-beam. Unlike other resists, the spun layer is inorganic (contains Si, O, and H, no C) which makes it very useful as an etch mask or for high temperature processing. It functions as a negative resist that can be developed in 2.38% TMAH or 25% TMAH for higher contrast. HSQ is VERY expensive and much higher maintenance to work with than any other photoresist. HSQ spontaneously turns into glass, and this crosslinking is facilitated by higher temperatures, exposure to water vapor, exposure to glass, exposure to the e-beam, and with time. Special handling procedures:
Relevant Papers: Improved time dependent performance of hydrogen silsesquioxane resist using a spin on top coat |
ZEP520A
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Not BNC supplied, must be purchased by individual research groups |
AR-P 6200
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BNC supplied photoresist |
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AR-P 6200 from AllResist, previously known as CSAR 62, is based on the same polymer as ZEP520A (a copolymer of a-chloromethacrylate and a-methylstyrene) with the addition of "0.5 % of a highly sensitive, thermo-stable, halogencontaining proprietary acid generator" (Chemical Semi-Amplified Positive E-Beam Resist CSAR 62 for Highest Resolution). The behavior of the two extremely similar, with AR-P6200/CSAR 62 exhibiting slightly increased sensitivity. https://arxiv.org/pdf/1611.07266.pdf https://avs.scitation.org/doi/pdf/10.1116/1.4899239 Thinner: Anisole, sold as AR 600-02, ZEP-A Adhesion Promoter: Diphenylsilanediol in PGMEA and Acetone, sold as AR 300-80 Some sources state that adhesion is typically excellent (e.g http://www.cnf.cornell.edu/cnf_process_ebl_resists.html#ZEP), and thus no promoter would be needed.
Developer: Amyl acetate, sold as AR 600-546 or ZED-N50 Alternate developers may be explored, see below for internal results from AllResist on possible alternates: Rinse: MIBK, sold as ZMD-D (e.g. http://research.engineering.ucdavis.edu/cnm2/wp-content/uploads/sites/11/2013/05/ZEP520ATechRepo.pdf) Stopper: Isopropanol, sold as AR 600-60 Remover: NMP Soak at 85 C for liftoff, also dissovles in room temperature NMP and acetone (though these may leave a residue). Heated NMP has been successfully used for liftoff, though the patterns still required sonication. Other removers alternately suggested by manufacturer, but not used at BNC:
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References
MicroChemicals Photoresist references:
General Properties of AZ/Ti Photoresists
Action of DNQ photoresists: