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Second IC :)

Homemade 1000+ transistor array chip 

In 2018 I made the first homemade integrated circuits in my garage
fab. I was a senior in high school when I made the Z1 amplifier, and
now I'm a senior in college so there are some long overdue
improvements to the amateur silicon process.
 DSC_9414ano
The Z1 had 6 transistors and was a great test chip to develop all the
processes and equipment. The Z2 has 100 transistors on a 10um
polysilicon gate process - same technology as Intel's first processor
. My chip is a simple 10x10 array of transistors to test,
characterize, and tweak the process but this is a huge step closer to
more advanced DIY computer chips. The Intel 4004 has 2,200
transistors and I've now made 1,200 on the same piece of silicon.

Screen Shot 2021-08-12 at 4.28.35 PM

Only half jokingOnly half joking

Previously, I made chips with a metal gate process. The aluminum gate
has a large work function difference with the silicon channel beneath
it which results in a high threshold voltage (>10V). I used these
metal gate transistors in a few fun projects like a guitar distortion
pedal and a ring oscillator LED blinker but both of these required
one or two 9V batteries to run the circuit due to high Vth. By
switching to a polysilicon gate process, I get a ton of performance
benefits (self aligned gate means lower overlap capacitances)
including a much lower Vth which makes these chips compatible with
2.5V and 3.3V logic levels. The new FETs have excellent
characteristics:

NMOS Electrical Properties:
Vth             = 1.1 V
Vgs MAX         = 8 V
Cgs             = <0.9 pF
Rise/fall time  = <10 ns
On/off ratio    = 4.3e6
Leakage current = 932 pA (Vds=2.5V)

I was particularly surprised by the super low leakage current. This
value goes up about 100x in ambient room lighting.

NMOS, 0.5V Vgs steps
NMOS, 0.5V Vgs steps
Diode curve
Diode curve
C-V showing Vth = 1.1V
C-V showing Vth = 1.1V

Now we know that it's possible to make really good transistors with
impure chemicals, no cleanroom, and homemade equipment. Of course,
yield and process repeatability are diminished. I'll do more testing
to collect data on the statistics and variability of FET properties
but it's looking good!

1MHz into 50O load
1MHz into 50O load
20MHz into 50O load
20MHz into 50O load

DSC_9419

The chip is small, about one quarter the die area of my previous ICs
(2.4mm^2) which makes it hard to probe. There's a simple 10x10 array
of N-channel FETs on each chip which will give me a lot of
characterization data. Since it's such a simple design, I was able to
lay it out using Photoshop. Columns of 10 transistors share a common
gate connection and each row is strung together in series with
adjacent transistors sharing a source/drain terminal. It's similar to
NAND flash but I only did this to keep the metal pads large enough so
I can reasonably probe them, if every FET had 3 pads for itself they
would be too small.

Source/drain
Source/drain
Poly gate
Poly gate
Contact
Contact
Metal
Metal

A single 10um NMOS transistor can be see below, with slight
misalignment in the metal layer (part of the left contact is
uncovered). Red outline is polycrystalline silicon, blue is the
source/drain.

Single NMOS transistor
Single NMOS transistor
Single NMOS transistor
Single NMOS transistor

So far I've made an opamp (Z1) and a memory-like array (Z2). More
interesting circuits are definitely possible even with this low
transistor density. The process needs some tweaking but now that I'm
able to consistently make good quality transistors I should be able
to design more complex digital and analog circuits. Testing each chip
is very tedious so I am trying to automate the process and I'll post
more data then. I've made 15 chips (1,500 transistors) and know
there's at least one completely functional chip and at least two
"mostly functional", meaning ~80% of the transistors work instead of
100%. No proper yield data yet. The most common defect is a drain or
source shorted to the bulk silicon channel, not a leaky or shorted
gate like on my Z1 process.

Profilometer scan of gateProfilometer scan of gate layer (y axis in
angstrom, x axis is micron)

I said before that the gate used to be made out of aluminum and now
it's silicon which makes the chips work a lot better. Silicon comes
in three varieties that we care about: amorphous, polycrystalline,
and monocrystalline. From left to right, these become more
electrically conductive but also much harder to deposit. In
fact, monocrystalline Si can't be deposited, you can only grow it in
contact with another mono-Si layer as a seed (epitaxy). Since the
gate must be deposited on top of an insulating dielectric, poly is
the best we can do. We can heavily dope the polysilicon anyway to
make it more conductive.

2 FETs sharing gate
2 FETs sharing gate
Neighbors share source/drain
Neighbors share source/drain

A typical self-aligned polysilicon gate process requires Silane,
a toxic and explosive gas, to deposit polycrystalline silicon layers.
It may also be possible by sputtering or evaporating amorphous
silicon and annealing with a laser. A major theme of this DIY silicon
process is to circumvent expensive, difficult, or dangerous steps.
So, I came up with a modified process flow. It's a variation on the
standard self-aligned methods to allow doping via high temperature
diffusion rather than ion implantation. The effect is that I'm able
to buy a silicon wafer with the polysilicon already deposited on
it from the factory and pattern it to make transistors instead of
putting my own polysilicon down halfway through the process. This is
a nice short term workaround but it would be best to design a
polysilicon deposition process using the laser anneal method
mentioned above.

Wafers are available with all kinds of materials deposited on them
already, so I just had to find one with a thin layer of SiO2 (gate
oxide, ~10nm) followed by a thicker polysilicon (300nm). I found a
lot of 25 200mm (EPI, prime, [1-0-0], p-type) wafers on eBay for $45
which is essentially a lifetime supply, so email me if you want one.
The gate oxide is the most fragile layer and requires the most care
during fabrication. Since I bought the wafer with a nice high quality
oxide on it already that was capped off and kept clean by the thick
polysilicon layer, I was able to eliminate all
the aggressive cleaning chemicals (sulfuric acid, etc) from the
process and still make great transistors. Minimal process chemicals
and tools are listed below.

Chemicals used in home poly-gate process:
-Water
-Alcohol
-Acetone
-Phosphoric acid
-Photoresist
-Developer (2% KOH)
-N type dopant (filmtronics P509)
-HF (1%) or CF4/CHF3 RIE
-HNO3 for poly etch or SF6 RIE

Equipment used in home poly-gate process:
-Hotplate
-Tube furnace
-Lithography apparatus
-Microscope
-Vacuum chamber to deposit metal

Z2 "gate first" process:

Buy wafer
Buy wafer
Etch active
Etch active
Dope source/drain
Dope source/drain
Etch poly gate
Etch poly gate
Deposit dielectric
Deposit dielectric
Etch contact
Etch contact
Deposit metal
Deposit metal
Etch metal
Etch metal

Some process subtleties are mentioned here, read this twitter thread.

This process isn't ideal and I want to make some changes so it's CMOS
compatible but it simplifies fabrication and makes it possible with a
minimal set of tools. The 1um dielectric layer (orange) would ideally
be CVD SiO2 (it's possible to build a TEOS oxide reactor at home) but
I used a photoresist instead. Most photoresists can be baked around
250degC to form a hard permanent dielectric layer that is an easy
alternative to CVD or PECVD oxide. A spin-on-glass/sol-gel could also
be used here.

Huge composite stitched die image:

0001_stitch

Thanks for following my work and feel free to contact me with your
thoughts at sam@zeloof.xyz !

Posted on August 12, 2021August 14, 2021Author szeloofCategories Home
Chip Lab

4 thoughts on "Second IC :)"

 1. Pingback: Garage chip fab - nickwinlund.net
 2. Pingback: Sam Zeloof's Upgraded Homemade Silicon IC Fab Process -
    Cyber News Network
 3. [039a2f] Giedrius says:
    August 14, 2021 at 7:46 am

    This is amazing! Keep up the good and interesting work.

    Reply
 4. [772def] David Tournatory says:
    August 14, 2021 at 5:12 pm

    Congrats, really amazing! So refreshing to see this kind of
    efforts in the semiconductor space.

    Reply

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