Packaging Recipes: Difference between revisions

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It is very helpful to also place alignment guides in the dicing streets, such as crosses at the intersections of dicing streets, such as this:
It is very helpful to also place alignment guides in the dicing streets, such as crosses at the intersections of dicing streets, such as this:


<code>         |</code>
<code>---- + ---- + ---- + ---</code>

<code>     |      |      |</code>


<code>---- + ---- + ---- + ---</code>
<code>---- + ---- + ---- + ---</code>
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A method to overcome this is to mount your sample with CrystalBond wax onto a Silicon carrier wafer. The wax is a much stronger adhesive. The drawback is that you must dissolve the wax to unmount your die, often resulting in a jumbled pile of small die in Acetone/Isopropanol, which can be difficult to handle/sort afterwards.
A method to overcome this is to mount your sample with CrystalBond wax onto a Silicon carrier wafer. The wax is a much stronger adhesive. The drawback is that you must dissolve the wax to unmount your die, often resulting in a jumbled pile of small die in Acetone/Isopropanol, which can be difficult to handle/sort afterwards.


<br />
To mount with wax onto a carrier wafer:
{| class="wikitable"

|+
- Prepare a clean silicon carrier wafers, at least ~5mm larger than your sample to be diced.
!Procedure to mount with wax onto a carrier wafer:

|-
- The Bay 5 solvent bench is most commonly used for wax mounting, although any solvent bench can be used as long as you cover the hotplate with wax and are careful to clean up any mess.
|

* Prepare a clean silicon carrier wafers, at least ~5mm larger than your sample to be diced.
- Cover the hotplate (cool) with clean tinfoil, and then raise temp to 130-150°C.
* The Bay 5 solvent bench is most commonly used for wax mounting, although any solvent bench can be used as long as you cover the hotplate with wax and are careful to clean up any mess.

* Cover the hotplate (cool) with clean tinfoil, and then raise temp to 130-150°C.
- Place the silicon carrier on top, polished wide up, and wait a few min for it to heat up. Pressing down with tweezers can help speed this up.
* Place the silicon carrier on top, polished wide up, and wait a few min for it to heat up. Pressing down with tweezers can help speed this up.

- Take either a small measured/weighed piece of crystalbond wax, or the whole stick, and touch/press it against the silicon carrier. The wax sticks are stored often on the bench shelves, edge of the bench, or the outside wall of the bench (where the vacuum ports are for the Bay 4 solvent bench).
* Take either a small measured/weighed piece of crystalbond wax, or the whole stick, and touch/press it against the silicon carrier. The wax sticks are stored often on the bench shelves, edge of the bench, or the outside wall of the bench (where the vacuum ports are for the Bay 4 solvent bench).
* Once a large enough puddle of melted wax is produced, remove the wax stick (use tweezers to hold the carrier wafer down), being careful to prevent the wax stringers from landing all over the workspace. You can clean it up later when the hotplate is cold.

** You want to make sure the entire underside of the sample will be contacting the wax, but don’t want so much wax that the sample will be tilted/uneven. Excess wax can easily be removed on an upcoming step.
- Once a large enough puddle of melted wax is produced, remove the wax stick (use tweezers to hold the carrier wafer down), being careful to prevent the wax stringers from landing all over the workspace. You can clean it up later when the hotplate is cold.
* With tweezers, place your sample to be diced on the wax, face up.

* Optional: press down the edges/corners of the sample to make it approximately flat.
You want to make sure the entire underside of the sample will be contacting the wax, but don’t want so much wax that the sample will be tilted/uneven. Excess wax can easily be removed on an upcoming step.
* Remove the entire tinfoil sheet, with carrier wafer, from the hotplate to let it cool down. Once cool (few mins), remove your silicon carrier with sample attached.

* Optional: To remove wax from the top surface of your sample, or from the edges, one effective way is to place the mounted assembly onto a POLOS spinner and, while spinning at ~1500-2000rpm, spray with ACE spray bottle for ~30sec, the ISO & N2 dry. This removes wax on the top without significantly attacking the wax mounting between the samples. You could also attempt to use a cotton swab with ACE, although this is typically much less clean.
- With tweezers, place your sample to be diced on the wax, face up.
* Proceed to apply your surface protection for dicing, eg. Photoresist coating or blue tape etc.

|-
- Optional: press down the edges/corners of the sample to make it approximately flat.
|''Procedure written by Demis D John, 2022-07-04. Please consider the [https://wiki.nanotech.ucsb.edu/wiki/Frequently_Asked_Questions#Publications_acknowledging_the_Nanofab publication policy].''

|}
- Remove the entire tinfoil sheet, with carrier wafer, from the hotplate to let it cool down. Once cool (few mins), remove your silicon carrier with sample attached.
<br />

- Optional: To remove wade from the top surface of your sample, or from

the edges, one effective way is to place the mounted assembly onto a POLOS spinner and, while spinning at ~1500-2000rpm, spray with ACE spray bottle for ~30sec, the ISO & N2 dry. This remove wax on the top without significantly attacking the wax mounting between the samples. You could also attempt to use a cotton

swab with ACE, although this is typically much less clean.

- Proceed to apply your surface protection for dicing, eg. Photoresist coating or blue tape etc.

''Procedure written by Demis D John, 2022-07-04''


===Dicing Tips===
===Dicing Tips===

Latest revision as of 18:18, 1 May 2024

Dicing Saw Recipes (ADT 7100)

Dicing Alignment Instructions

The Process Group often has users fill out these instructions below to fully define a dicing job. This will ensure you have thought about the entire dicing process.

Note that you should design your chips with ≥250µm dicing street width, to avoid the blade cutting into your devices.

It is very helpful to also place alignment guides in the dicing streets, such as crosses at the intersections of dicing streets, such as this:

---- + ---- + ---- + ---

     |      |      |

---- + ---- + ---- + ---

     |      |      |

---- + ---- + ---- + ---

Recommended Dicing Parameters

This table is for our stocked Thermocarbon Resnoid blades.

-2C blades are 2mils/50µm wide, -4C blades are 4mils/100µm wide, and -8C blades are 8mils/200µm wide. Plan for ~10–30µm extra edge clearance to account for kerf, chipping, etc.

Narrower (~30-50µm) Nickel Hubbed blades are often used for even narrower dicing streets, these must be purchased by the user. KnS G1440-Q5H0 work very well, with ~30µm blade width and smaller kerf. You need to insert a shim to use these blades - please contact tool supervisor for how to use these blades.

Material Blade P/N Spindle Speed

(KRPM)

Cut Speed

(mm/s)

Alumina, AlN 2.187-8C-54RU-3 25 0.5-2
Ceramic 2.187-4C-30RU-3 18 0.5-2
GaAs 2.187-4C-9RU-3 35 1-5
GaN  (<550um) 2.187-4C-30RU-3 35 0.5-3
GaN  (>550um) 2.187-8C-30RU-3 35 0.5-2
Glass/Fused Silica 2.187-4C-22RU-3 25 1-5
InP 2.187-4C-9RU-3 35 1-5
Quartz 2.187-4C-30RU-3 25 1-5
Sapphire 2.187-8C-54RU-3 18 0.5-2
Si 2.187-2C-9RU-3 30 1-2
Si 2.187-4C-9RU-3 35 4-10
Si on Glasss 2.187-4C-9RU-3 25 1-5
SiC 2.187-8C-30RU-3 25 0.5-2
Ti 2.187-8C-54RU-3 15 0.5-2

Anatomy of a Blade

Example: 2.187-4C-9RU-3

"2.187": This is the blade Outer Diameter ("OD") in inches (55.55 mm).

"4C": Blade thickness in mils. 4 mil = 100 µm

"9": Diamond particle size in microns. Stocked resin blades have embedded diamond particles. Smaller particles create a smoother kerf, but remove less material and are thus less robust or require slower cutting speeds.

"RU-3". A blade parameter that deals with cut quality vs. robustness (lifetime) of the blade.

Calculated Blade Exposures

Blade Diam Flange Diam. Blade Exposure
2.187" (55.55 mm) 47 mm 4.275 mm
2.187" (55.55 mm) 49 mm 3.275 mm
2.187" (55.55 mm) 51 mm 2.275 mm
2.187" (55.55 mm) 52 mm 1.775 mm
2.187" (55.55 mm) 53 mm 1.275 mm

Blade Exposure Calculation

schematic of blade exposure
Diagram of blade exposure. If A < 0.30mm, then the flange may hit your wafer, damaging the tool and wafer!

Mounting/Unmounting Samples

The UV-Release Tape dispenser is most-often used for mounting sample for dicing.

The Tape Model installed is Ultron 1042R. Data Sheet Here.

Wax-Mounting to Carrier

If your final die size will be very small, eg. <3mm square or so, the chances increase that many die will be ejected into the cooling water stream once you begin the 2nd cut angle, because the total surface area of die contacting the adhesive tape becomes very low

A method to overcome this is to mount your sample with CrystalBond wax onto a Silicon carrier wafer. The wax is a much stronger adhesive. The drawback is that you must dissolve the wax to unmount your die, often resulting in a jumbled pile of small die in Acetone/Isopropanol, which can be difficult to handle/sort afterwards.


Procedure to mount with wax onto a carrier wafer:
  • Prepare a clean silicon carrier wafers, at least ~5mm larger than your sample to be diced.
  • The Bay 5 solvent bench is most commonly used for wax mounting, although any solvent bench can be used as long as you cover the hotplate with wax and are careful to clean up any mess.
  • Cover the hotplate (cool) with clean tinfoil, and then raise temp to 130-150°C.
  • Place the silicon carrier on top, polished wide up, and wait a few min for it to heat up. Pressing down with tweezers can help speed this up.
  • Take either a small measured/weighed piece of crystalbond wax, or the whole stick, and touch/press it against the silicon carrier. The wax sticks are stored often on the bench shelves, edge of the bench, or the outside wall of the bench (where the vacuum ports are for the Bay 4 solvent bench).
  • Once a large enough puddle of melted wax is produced, remove the wax stick (use tweezers to hold the carrier wafer down), being careful to prevent the wax stringers from landing all over the workspace. You can clean it up later when the hotplate is cold.
    • You want to make sure the entire underside of the sample will be contacting the wax, but don’t want so much wax that the sample will be tilted/uneven. Excess wax can easily be removed on an upcoming step.
  • With tweezers, place your sample to be diced on the wax, face up.
  • Optional: press down the edges/corners of the sample to make it approximately flat.
  • Remove the entire tinfoil sheet, with carrier wafer, from the hotplate to let it cool down. Once cool (few mins), remove your silicon carrier with sample attached.
  • Optional: To remove wax from the top surface of your sample, or from the edges, one effective way is to place the mounted assembly onto a POLOS spinner and, while spinning at ~1500-2000rpm, spray with ACE spray bottle for ~30sec, the ISO & N2 dry. This removes wax on the top without significantly attacking the wax mounting between the samples. You could also attempt to use a cotton swab with ACE, although this is typically much less clean.
  • Proceed to apply your surface protection for dicing, eg. Photoresist coating or blue tape etc.
Procedure written by Demis D John, 2022-07-04. Please consider the publication policy.


Dicing Tips

Harder materials will often require larger diamond particle sizes, and thicker blades will last longer if they are overheating and breaking often.

It is not uncommon to have to change a blade in the middle of cutting a wafer - the software is set up to allow this easily without aborting the programmed cuts. The "Height Check Rate" in the recipe will check the blade exposure after this many cuts, using the optical height sensor - this allows you to see how quickly the blade is wearing out (as blade exposure reduces).

Ensuring the cut water jet is hitting at ~7-8 o'clock on the blade and the water jet is being split in two will keep the blade coolest and help prevent breakage. Water sprays should be set to 0.9/0.9/0.9 by default.

For sapphire dicing (very hard material), it is common to use "double-pass dicing", where the substrate is cut at only half depth (eg. cutting only 150µm deep for a 300µm thick substrate) on the first pass, and then re-cut at the full depth. The blade will need to be changed often, so set your "Height Check Rate" to 1 or 2. This can be very time consuming. 200-300µm thick Sapphire substrates are much easier to cut than 650µm thick - often single-pass dicing is adequate for the thinner substrates.

Surface Protection

Photoresist

Users most often use sacrificial photoresists to protect the surface from accumulating dicing dust. The static-buildup of dielectric films causes the dust to adhere strongly. Ensure that the PR thickness will adequately coat all your exposed topography (eg. use a ≥2µm thick PR for protecting 1.5-2.0µm tall etched features).

  1. Choose a photoresist of appropriate thickness, and spin-coat it & soft-bake it according to a standard recipe.
    1. Contact Alignment PR Recipes
    2. Stepper PR Recipes
  1. Perform your dicing
  2. Remove the die from the UV release tape (60sec UV Exposure)
  3. Strip the PR from each die in Acetone and ISO & N2 dry. We recommend to use ACE/ISO squirt bottles on each die individually to ensure the particles on the PR surface don’t land and stick to the chip surface.

Blue Tape

Alternatively our low-tack residue-free Blue tape can be used to protect the die surface. Blue tape removal is easy for large die, but does require manual removal from each die, and eliminates sample exposure to solvents.

The very edges of the die may accumulate a bit more dicing dust due to the tape delaminating slightly during dicing. Plan for about 50-100µm of edge clearance on each die.

Wafer Bonder (Logitech WBS7)

This tool is used for bonding samples to Silicon carrier wafers with CrystalBond wax.

Automated Wafer Cleaver (Loomis LSD-155LT)

This tool is used for scribe and break of your samples.

  • Recommended recipes, a starting point for most applications.