Specific Process Knowledge/Etch/DRIE-Pegasus/Pegasus-2/ORE with Al2O3 mask: Difference between revisions

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=Al<sub>2</sub>O<sub>3</sub> mask=
=Al<sub>2</sub>O<sub>3</sub> mask=


[[File:esq met Al2O3 compact.jpg|500px|right|thumb|'''''Scheme of the sample fabrication using Al<sub>2</sub>O<sub>3</sub> mask. These samples were coated with either 50 or 100 nm of Al<sub>2</sub>O<sub>3</sub>, followed by 65 nm of BARC and 750 nm of DUV resist. Not at scale. <br>
[[File:esq met Al2O3 compact.jpg|400px|right|thumb|'''''Scheme of the sample fabrication using Al<sub>2</sub>O<sub>3</sub> mask. These samples were coated with either 50 or 100 nm of Al<sub>2</sub>O<sub>3</sub>, followed by 65 nm of BARC and 750 nm of DUV resist. Not at scale. <br>
Scheme: Maria Farinha, @DTU Nanolab''''']]
Scheme: Maria Farinha, @DTU Nanolab''''']]



Revision as of 14:01, 31 January 2023

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By Maria Farinha @Nanolab Internal, Jan 2023

Al2O3 mask

Scheme of the sample fabrication using Al2O3 mask. These samples were coated with either 50 or 100 nm of Al2O3, followed by 65 nm of BARC and 750 nm of DUV resist. Not at scale.
Scheme: Maria Farinha, @DTU Nanolab

In these samples, the hard mask, Al2O3, was coated in 150 mm Si wafers using the ALD 1 tool. These sets of samples also had the lithography process done in the DUV stepper to deposit 65 nm of BARC and 750 nm of DUV resist. Three different patterns were created after the development:

  1. Pillars of 1 µm with 1 µm pitch (50 nm Al2O3 + 65 nm BARC + 750 nm DUV).
  2. Holes of 1 µm with 1 µm pitch (50 nm Al2O3 + 65 nm BARC + 750 nm DUV).
  3. Nanoholes of 200 nm with 400 nm pitch (100 nm Al2O3 + 65 nm BARC + 750 nm DUV).

The Si / Al2O3 / BARC / DUV stack was first processed in Pegasus 2 to etch the BARC layer, and the alumina was etched in the III-V ICP, using a BCl3 / Ar recipe. With pillars and holes, the BARC was etched for 12 min on Pegasus 2, followed by 90 minutes on the III-V ICP. The nanoholes had two different approaches, starting with 260 minutes on the III-V ICP. However, it was seen that after the III-V ICP process, the leftover resist on the sample was removed during the CORE process on Pegasus 2.

Samples profile before going for the ORE process:
After Al2O3 etch Comments
1 µm pillars Visible that after the 90 min Al2O3 etch, the mask was correctly etched away confirmed by reaching the silicon (etched ~30nm of it).
1 µm holes Visible that after the 90 min Al2O3 etch, the mask was correctly etched away confirmed by reaching the silicon (etched ~16nm of it).
200nm nanoholes 2 220 mTorr




ORE process

Important! The pressure settings used below may no longer be permitted, always check with the Dry etch group.

As stated by Nguyen et al., the SF6 and O2 fluxes are only separated after 4 s during the C-step. Shorter time steps than that do not execute the function of the clearing. After testing recipes with only 2 s of clearing and with no clear step, it was understood it could be eliminated, showing more depth as well as less undercut when going for shorter cycles. From then on, not CORE but ORE recipes were applied D/E = O/RE.
Moreover, during the E-step, the MFC (mass flow controller) presented a delay to read the pressure when compared with the power, creating unwanted bias. To fight it, the E-step was divided into E1 and E2. The E1 of only 2 s is enough to stabilize the pressure, and E2 the profile is etched correctly, without the unwanted bias.

CORE process graphics and recipes: a) unwanted DC bias during the E-step; b) E-step separated into two steps, E1 decreased the bias.
Scheme: Maria Farinha @DTU Nanolab, March 2022

Going further, the process is set with 4 steps, Oxidize, Removal, E1 and E2 steps. In the E1, the pressure will rise, without power applied, so for the E2 the pressure is already rising and the power starts to be applied.

Pillars

Using patterned samples of 1 μm pillars with 50 nm of Al2O3. After the tests, approximately 32nm of Al2O3 were still intact. During the recipe, Pegasus 2 conditions were: Outer EM=10A, T=20°C, no clamping, no He BGC, no coil power and all heaters OFF.

Pillars with different etching times.
Photo: Maria Farinha @DTU Nanolab, March 2022
1μm Pillar recipe from March 2022 - #244 = 122 min
Time (s) Pressure (valve control) O2 flow (SCCM) SF6 flow (SCCM) Platen power (W)
O-step 10 3% 200 0 40
R-step 10 100% 0 5 40
E1-step 2 4% 0 350 40
E2-step 7 4% 0 350 300

* Pillars profile effect when varying the etch time.


Holes

Using patterned samples of 1 μm holes with 50 nm of Al2O3. After the tests, approximately 28nm of Al2O3 were still intact. When using this recipe, by adjusting the number of cycles, approximately 10 μm was achieved maintaining a straight profile. When going for deeper profiles, 17 μm was also achieved, but the profile started to get positive. Further work may solve the issue. During the recipe, Pegasus 2 conditions were: Outer EM=10A, T=20°C, no clamping, no He BGC and all heaters OFF.

Holes profile. #144 cycles for 60 min and #288 cycles for 120 min.
Photo: Maria Farinha @DTU Nanolab, March 2022
1μm holes recipe
Time (s) Pressure O2 flow (SCCM) SF6 flow (SCCM) Platen power (W) Coil power (W)
O-step 10 220 mTorr 200 0 40 0
R-step 10 100% 0 40 40 0
E1-step 2 220 mTorr 0 1200 0 0
E2-step 1-5 220 mTorr 0 1200 1 2000

* For #288 cycles, 120 min, the profile depth reaches 17.6 μm. For #144 cycles, 60 min, the profile depth reaches 10.1 μm. Width variation presented in the pictures.


Nanoholes

The nanoholes are 200nm wide, with 400nm pitch with 100 nm Al2O3 mask. During the recipe, Pegasus 2 conditions were: Outer EM=10A, T=20°C, no clamping, no He BGC and all heaters OFF.

Nanoholes profile when varying the removal power.
Photo: Maria Farinha @DTU Nanolab, April 2022
200nm nanoholes recipe, varying R-power
Time (s) Pressure (valve control) O2 flow (SCCM) SF6 flow (SCCM) Platen power (W)
O-step 10 220 mTorr 200 0 40
R-step 10 100% 0 40 *
E1-step 2 220 mTorr 0 350 0
E2-step 0-15 220 mTorr 0 350 100-300

*The R-power value was changed and observed.


The most suitable removal power was 40 W, removing the bottom of the profile correctly without damaging the top part of the profile.

Nanoholes profile when varying the ramping E-time .
Photo: Maria Farinha @DTU Nanolab, July 2022
200nm nanoholes recipe, varying E-ramping time
Time (s) Pressure (valve control) O2 flow (SCCM) SF6 flow (SCCM) Platen power (W)
O-step 10 220 mTorr 200 0 40
R-step 10 100% 0 40 40
E1-step 2 220 mTorr 0 350 40
E2-step * 220 mTorr 0 350 300

*The E2-time value was changed and observed.


Regarding the measurements of the profiles, in a) the depth reached 3.17 µm with 0-15s of ramping, b) reached 3.21 µm with 1-15s of ramping, c) reached 2.87 µm whit 5-15s of ramping and d) reached 3.63 µm with 15 s without ramping.


Isotropic etch

Some isotropic etches were performed, intercalated with anisotropic etches. The nanoholes are 200nm wide, with 400nm pitch with 100 nm Al2O3 mask. The recipe presented in the table was repeated either 2 or 3 times in order to achieve the picture results. During the recipe, Pegasus 2 conditions were: Outer EM=10A, T=20°C, no clamping, no He BGC and all heaters OFF.

x2 anisotropic + isotropic etch.
Photo: Maria Farinha @DTU Nanolab, June 2022
Table: nanoholes + isotropic etch
Time (s) Pressure O2 flow (SCCM) SF6 flow (SCCM) Platen power (W) Coil power (W)
Nanoholes etch O-step 10 220 mTorr 200 0 40 0
R-step 10 100% 0 0 40 0
E1-step 2 220 mTorr 0 350 0 0
E2-step 0-15 220 mTorr 0 350 100-300 0
Isotropic etch O-step 30 200 mTorr 200 0 0 2000
R-step 30 100% 0 40 40 0
E-step 20 200 mTorr 0 1200 0 2000


x3 anisotropic + isotropic etch.
Photo: Maria Farinha @DTU Nanolab, June 2022