PROCESSING GUIDELINES FOR:
SU-8 2025, SU-8 2035, SU-8 2050 and SU-8 2075
SU-8 2000is a high contrast, epoxy based photoresist designed for micromachining and other microelectronic applications, where a thick, chemically and thermally stable image is desired. SU-8 2000 is an improved formulation of SU-8, which has been widely used by MEMS producers for many years. The use of a faster drying, more polar solvent system results in improved coating quality and increases process throughput. SU-8 2000 is available in twelve standard viscosities. Film thicknesses of 0.5 to >200 microns can be achieved with a single coat process. The exposed and subsequently thermally cross-linked portions of the film are rendered insoluble to liquid developers. SU-8 2000 has excellent imaging characteristics and is capable of producing very high aspect ratio structures. SU-8 2000 has very high optical transmission above 360 nm, which makes it ideally suited for imaging near vertical sidewalls in very thick films. SU-8 2000 is best suited for permanent applications where it is imaged, cured and left on the device.
Processing Guidelines
SU-8 2000 photoresist is most commonly exposed with conventional UV (350-400 nm) radiation, although i-line (365 nm) is the recommended wavelength. SU-8 2000 may also be exposed with e-beam or x-ray radiation. Upon exposure, cross-linking proceeds in two steps (1) formation of a strong acid during the exposure step, followed by (2) acid-catalyzed, thermally driven epoxy cross-linking duri
ng the post exposure bake (PEB) step. A normal process is: spin coat, soft bake, expose, PEB, followed by develop. A controlled hard bake is recommended to further cross-link the imaged SU-8 2000 structures when they will remain as part of the device. The entire process should be optimized for the specific application.The baseline information presented here is meant to be used as a starting point for determining a process.
SU-8 2000 Features
•High aspect ratio imaging
•0.5 to > 200 μm film thickness in a single coat •Improved coating properties
•Faster drying for increased throughput •Near UV (350-400 nm) processing •Vertical sidewalls
10 um features, 50 um SU-8 2000 coating
Substrate Pretreat
Hard Bake (cure)
optional Removal optional
Process Flow
Coat
Expose
Edge Bead Removal (EBR)
Soft Bake
Develop
Post Exposure Bake (PEB)
Rinse and Dry
Substrate Preparation
To obtain maximum process reliability, substrates should be clean and dry prior to applying SU-8 2000 resist. For best results, substrates should be cleaned with a piranha wet etch (using H 2SO 4& H 2O 2) followed by a de-ionized water rinse. Substrates may also be cleaned using reactive ion etching (RI
E) or any barrel asher supplied with oxygen. Adhesion promoters are typically not required. For applications that include electroplating, a pre-treatment of the substrate with MCC Primer 80/20 (HMDS) is recommended.
Coat
SU-8 2000 resists are available in twelve standard viscosities. This processing guideline document addresses four products: SU-8 2025, SU-8 2035, SU-8 2050 and SU-8 2075. Figure 1. provides the information required to select the appropriate SU-8 2000 resist and spin conditions to achieve the desired film thickness.
Recommended Program
1.) Dispense 1ml of resist for each inch (25mm) of substrate diameter.
2.) Spin at 500 rpm for 5-10 seconds with acceleration of 100 rpm/second.
3.) Spin at 2000 rpm for 30 seconds with acceleration of 300 rpm/second.
Edge Bead Removal (EBR)
During the spin coat process step, a build up of photoresist
may occur on the edge of the substrate. In order to minimize contamination of the hotplate, this thick bead should be removed. This can be accomplished by using a small stream of solvent (MicroChem’s EBR PG) at the edge of the wafer either at the top or from the bottom. Most automated spin coaters now have this feature and can be programmed to do this automatically.
By removing any edge bead, the photomask can be placed into close contact with the wafer, resulting in improved resolution and aspect ratio.
Soft Bake
A level hotplate with good thermal control and uniformity is recommended for use during the Soft Bake step of the process. Convection ovens are not recommended. During convection oven baking, a skin may form on the resist. This skin can inhibit the evolution of solvent, resulting in incomplete drying of the film and/or extended bake times. Table 2. shows the recommended Soft Bake temperatures and times for the various SU-8 2000 products at selected film thicknesses.
Note: To optimize the baking times/conditions, remove the wafer from the hotplate after the prescribed
time and allow it to cool to room temperature. Then, return the wafer to the hotplate. If the film ‘wrinkles’, leave the wafer on the hotplate for a few more minutes. Repeat the cool-down and heat-up cycle until ‘wrinkles’are no longer seen in the film.
Table 2. Soft Bake Times
Table 1. SU-8 2000 Viscosity
Figure 1. SU-8 2000 Spin Speed versus Thickness
500
10001500200025003000350040004500
Spin Speed (rpm)
F i l m T h i c k n e s s (u m )
THICKNESS
PEB TIME (65o C)*PEB TIME
(95o C)
microns
minutes
minutes
25 -40
1 5 -645 -80 1 -
2 6 -785 -110 2 -58 -10115 -150510 -12160 -225512 -15
* Optional step for stress reduction
Figure 3. Cauchy Coefficients
Table 3. Exposure Dose
RELATIVE DOSE
Silicon 1X Glass 1.5X Pyrex
1.5X Indium Tin Oxide 1.5X Silicon Nitride 1.5 - 2X Gold
1.5 - 2X Aluminum 1.5 - 2X Nickel Iron 1.5 - 2X Copper 1.5 - 2X Nickel 1.5 - 2X Titanium
1.5 - 2X
Table 4. Exposure Doses for Various Substrates
Post Exposure Bake (PEB)
PEB should take place directly after exposure. Table 5. shows
the recommended times and temperatures
Note: After 1 minute of PEB at 95°C, an image of the mask should be visible in the SU-8 2000 photoresist coating. If no visible latent image is seen during or after PEB this means that there was insufficient exposure, heating or both.
Table 5. Post Exposure Bake Times
Optical Parameters
The dispersion curve and Cauchy coefficients are shown in Figure 3. This information is useful for film
thickness measurements based on ellipsomety and other optical measurements.
Exposure
To obtain vertical sidewalls in the SU-8 2000 resist, we recommend the use of a long pass filter to eliminate UV radiation below 350 nm. With the recommended filter (PL-360-LP) from Omega Optical (afilters ) or Asahi Technoglass filters V-42 plus UV-D35 (jp), an increase in exposure time of approximately 40% is required to reach the optimum exposure dose.
Note: With optimal exposure, a visible latent image will be seen in the film within 5-15 seconds after being placed on the PEB hotplate and not before. An exposure matrix experiment should be performed to determine the optimum dosage.
n 1.566n 0.00796n 0.00014
SU-8 Cauchy
Coefficients (uncured)
THICKNESS
EXPOSURE ENERGY
microns
mJ/cm
2
25 -40150 -16045 -80150 -215 85 -110215 -240115 -150240 -260 160 -225260 -350
Development
SU-8 2000 photoresist has been designed for use in immersion, spray or spray-puddle processes with MicroChem’s SU-8 developer. Other solvent based developers such as ethyl lactate and diacetone alcohol may also be used. Strong agitation is recommended when developing high aspect ratio and/or thick film structures. The recommended development times for immersion processes are given in Table 6. These development times are approximate, since actual dissolution rates can vary widely as a function of agitation
Note: The use of an ultrasonic or megasonic bath may be helpful when developing out via or hole patterns or structures with tight pitch.
Rinse and Dry
When using SU-8 developer, spray and wash the developed image with fresh solution for approximately 10 seconds, followed by a second spray/wash with Isopropyl Alcohol (IPA) for another 10 seconds. Air dry with filtered, pressurized air or nitrogen.
Note: A white film produced during IPA rinse is an indication of underdevelopment of the unexposed photoresist. Simply immerse or spray the substrate with additional SU-8 developer to remove the white film and complete the development process. Repeat the rinse step.
The use of an ultrasonic or megasonic bath will energize the solvent and allow for more effective development of the
unexposed resist.
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Table 6. Development Times for SU-8 Developer
Table 7. Physical Propeties
Figure 4. Optical Transmittance
10
2030405060708090100320360400440480520560600640680720760800
Wavelength (nm)
T r a n s m i t t a n c e (%)
Process conditions for Figure 4.Softbake: 5 minutes at 95°C Exposure: 180 mJ/cm 2
Hardbake: 30 minutes at 300°C
Physical Properties
(Approximate values)
Optical Properties
Hard Bake (cure)
SU-8 2000 has good mechanical properties. However, for applications where the imaged resist is to be left as part of the final device, a hard bake can be incorporated into the process. This is generally only required if the final device or part is to be subject to thermal processing during regular operation. A hard bake or final cure step is added to ensure that SU-8 2000 properties do not change in actual use. SU-8 2000 is a thermal resin and as such its properties can continue to change when exposed to a higher temperature than previously encountered. We recommend using a final bake temperature 10°C higher than the maximum expected device operating temperature. Depending on the degree of cure required, a bake temperature in the range of 150°C to 250°C and for a time between 5 and 30 minutes is typically used.
Note:The hard bake step is also useful for annealing any surface cracks that may be evident after development. The recommended step is to bake at 150°C for a couple of minutes. This applies to all film thicknesses.
Removal
SU-8 2000 has been designed as a permanent, highly cross-linked epoxy material and it is extremely difficult to remove it with conventional solvent based resist strippers. MicroChem’s Remover PG will swell and lift off minimally cross-linked SU-8 2000. However, if OmniCoat (30-100 nm) has been applied, immersion in Remover PG can effect a clean and thorough Lift-Off of the SU-8 2000 material. Fully cured or hard baked SU-8 2000 cannot be removed without the use of OmniCoat.
To remove minimally cross-linked SU-8 2000, or when using Omnicoat: Heat the Remover PG bath to 50-80°C and immerse the substrates for 30-90 minutes. Actual strip time will depend on resist thickness and cross-link density For more information on MicroChem Omnicoat and Remover PG please see the relevant product data sheets.
To re-work fully cross-linked SU-8 2000: Wafers can be stripped using oxidizing acid solutions such as piranha etch, plasma ash,RIE, laser ablation and pyrolysis.
Plasma Removal
RIE 200W, 80 sccm O 2, 8 sccm CF 4, 100mTorr, 10°C
Storage
Store SU-8 2000 resists upright and in tightly closed containers in a cool, dry environment away from direct sunlight at a temperature of 40-70°F (4-21°C). Store away from light, acids, heat and sources of ignition. Shelf life is twelve months from date of manufacture.
Disposal
SU-8 2000 resists may be included with other waste containing similar organic solvents to be discarded for destruction or reclaim in accordance with local state and federal regulations. It is the responsibility of the customer to ensure the disposal of SU-8 2000 resists and residues made in observance all federal, state, and local environmental regulations.
Environmental, Health and Safety
Consult the product Material Safety Data Sheet before working with SU-8 2000 resists. Handle with care. Wear chemical goggles, chemical gloves and suitable protective clothing when handling SU-8 2000 resists. Do not get into eyes, or onto skin or clothing. Use with adequate ventilation to avoid breathing vapors or mist.In case of contact with skin, wash affected area with soap and water. In case of contact with eyes, rinse immediately with water and flush for 15 minutes lifting eyelids frequently. Get emergency medical assistance.
The information is based on our experience and is, we believe to be reliable, but may not be complete. We make no guarantee or warranty, expressed or implied, regarding the information, use, handling, storage, or possession of these products, or the application of any process described herein or the results desired, since the conditions of use and handling of these products are
beyond our control.
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Disclaimer
Notwithstanding anything to the contrary contained in any sales documentation, e.g., purchase order forms, all sales are made on the following conditions:
All information contained in any MicroChem product literature reflects MicroChem’s current knowledge on the subject and is, we believe, reliable. It is offered solely to provide possible suggestions for customer’s own experiments and is not a substitute for any testing by customer to determine the suitab
ility of any of MicroChem products for any particular purpose. This information may be subject to revision as new knowledge and experience becomes available, but MicroChem assumes no obligation to update or revise any data previously furnished to a customer; and if currency of data becomes an issue, customer should contact MicroChem requesting updates. Since MicroChem cannot anticipate all variations in actual end uses or in actual end-use conditions, it makes no claims, representations or warranties, express or implied including, without limitation any warranty of merchantability or fitness for a particular purpose; and customer waives all of the same. MicroChem expressly disclaims any responsibility or liability and assumes no responsibility or liability in connection with any use of this information including, without limitation, any use, handling, storage or possession of any MicroChem products, or the application of any process described herein or the results desired or anything relating to the design of the customer’s products. Nothing in this publication is to be considered as a license to operate under or a recommendation to infringe any patent right.
Caution
This product is not designed or manufactured for, nor is it intended for use in any medical device or for any other medical application. Do not use this product in any medical applications [including, without limitation, any permanent implantation in the human body or any animals (other than laboratory animal
s used for experimental purposes), or contact with internal body fluids or tissues] unless otherwise expressly and specifically provided for in a written contract between MCC and the customer. The complete MicroChem Medical Disclaimer Statement is available upon request or on the MicroChem website at www.microchem.
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