Specific Process Knowledge/Etch/III-V ICP/InP-InGaAsP-InGaAs: Difference between revisions

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This work was done with great inspiration from the following articles:
This work was done with great inspiration from the following articles:
*Sidewall passivation assisted by a silicon coverplate during and HBr inductively coupled plasma etching of InP for photonic devices ''by S. Bouchoule, G. Patriarche, S. Guilet, L. Gatilova, L. Largeau, and P. Chabert'', Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena 26, 666 (2008); doi: 10.1116/1.2898455
*'''Sidewall passivation assisted by a silicon coverplate during and HBr inductively coupled plasma etching of InP for photonic devices''' ''by S. Bouchoule, G. Patriarche, S. Guilet, L. Gatilova, L. Largeau, and P. Chabert'', Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena 26, 666 (2008); doi: 10.1116/1.2898455


*Optimization of a inductively coupled plasma etching process adapted to nonthermalized InP wafers for the realization of deep ridge heterostructures, ''by S. Guilet, S. Bouchoule, C. Jany, C. S. Corr, and P. Chabert'', Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena 24, 2381 (2006); doi: 10.1116/1.2348728
*'''Optimization of a inductively coupled plasma etching process adapted to nonthermalized InP wafers for the realization of deep ridge heterostructures''', ''by S. Guilet, S. Bouchoule, C. Jany, C. S. Corr, and P. Chabert'', Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena 24, 2381 (2006); doi: 10.1116/1.2348728


*Investigation of InP etching mechanisms in a inductively coupled plasma by optical emission spectroscopy, ''by L. Gatilova, S. Bouchoule, S. Guilet, and P. Chabert'', Journal of Vacuum Science & Technology A 27, 262 (2009); doi: 10.1116/1.3071950
*'''Investigation of InP etching mechanisms in a inductively coupled plasma by optical emission spectroscopy''', ''by L. Gatilova, S. Bouchoule, S. Guilet, and P. Chabert'', Journal of Vacuum Science & Technology A 27, 262 (2009); doi: 10.1116/1.3071950





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InP etch with HBr chemistry (2019)

Work done by Aurimas Sakanas @Fotonik.dtu 2019. This work was done to obtain very low surface roughness.

Recipe name ?
HBr flow 10 sccm
CH4 flow 5 sccm
Ar flow 2 sccm
Platen power 50 W
Coil power 600 W
Pressure 5 mTorr
Platen chiller temperature 180 oC
Comment Sample crystal bonded (Crystalbond 509, clear color) to Si carrier
Results
Etch rate

250-350 nm/min (2" wafer)
350-450 nm/min (quarter of a 2" wafer)

Sidewall angle

85-87o (bottom)
93-95o (top)
Concave profile

Selectivity (InP:HSQ) 15:1 (2"), 20:1
Other tests Comparing this recipe with the Cl2/H2 recipe, click here: Media:HBr vs Cl2 InP etch comparison Aurimas.pptx (By Aurimas Sakana @photonic (nov 2019))

InP etch with Cl2/H2 and a Si carrier wafer (2019)

Work done by Berit Herstrøm @Nanolab spring 2019
This work was done with great inspiration from the following articles:

  • Sidewall passivation assisted by a silicon coverplate during and HBr inductively coupled plasma etching of InP for photonic devices by S. Bouchoule, G. Patriarche, S. Guilet, L. Gatilova, L. Largeau, and P. Chabert, Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena 26, 666 (2008); doi: 10.1116/1.2898455
  • Optimization of a inductively coupled plasma etching process adapted to nonthermalized InP wafers for the realization of deep ridge heterostructures, by S. Guilet, S. Bouchoule, C. Jany, C. S. Corr, and P. Chabert, Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena 24, 2381 (2006); doi: 10.1116/1.2348728
  • Investigation of InP etching mechanisms in a inductively coupled plasma by optical emission spectroscopy, by L. Gatilova, S. Bouchoule, S. Guilet, and P. Chabert, Journal of Vacuum Science & Technology A 27, 262 (2009); doi: 10.1116/1.3071950


Recipe name ?
Cl2 flow 6.6 sccm
H2 flow 5.4 sccm
Process time 6 min
Platen power 150 W
Coil power 800 W
Pressure 0.5 mTorr (strike pressure 10s@10mTorr)
Platen chiller temperature 180 oC
Comment Sample placed on a Si carrier
Results
Etch rate

925 nm/min (small piece)

Sidewall angle

90o (on this sample)
If you get a small tapered profile try lowering the platen power (to e.g. 100W), this will also decrease the etch rate

Selectivity (InP:SiO2 (PECVD 500nm) approx.17:1
Other tests made

InP etch with Cl2/CH4/Ar 2013

Work done by Matthew Haines in 2013

InP/InGaAsP/InGaAs etch 2011

Unselective etch for large sized features and small aspect ratios by David Larsson, DTU Photonics, 2011

Recipe InP Etch 1/InP Precond 1 ?
Cl2 flow 20 sccm 11 sccm
N2 flow 40 sccm 20 sccm
Ar flow 10 sccm 24 sccm
Platen power 100 W 120 W
Coil power 500 W 400 W
Pressure 2 mTorr 2 mTorr
Platen chiller temperature 180 oC 180 oC
Comment This is for large structures with samll aspect ratio
Use SiO2 carrier (not Si) (Kabi/Bghe June 2018)
This is for high aspect ratio


Results (InP Etch 1)
Etch rate 500-600 nm/min
Sidewall angle 86-87 o
Selectivity (InP:SiO2, InP:HSQ) 50:1

InP etching June 2018

Done by Kabi and Bghe @nanolab

Sample pattern before etching

Etching of an InP piece on Si carrier

InP piece patterned with SiO2. The piece was etched on top of a Si wafer without bonding. The recipe "InP etch" was used. The roughness looks high in the bottom of the etched areas, especially in the large open areas.

Etching of an InP piece on SiO2 carrier

InP piece patterned with SiO2. The piece was etched on top of a Si wafer coated with SiO2 without bonding. The recipe "InP etch" was used. The roughness looks low in the bottom of the etched areas, even in the large open areas.


Changing the Cl2/N2 ratio