Difference between revisions of "Wet Etching Recipes"

Revision as of 18:29, 6 April 2020

See the Master Wet Etching Table at the bottom of this page for wet-etch rates in various experiments we have tested.

References

Etch rates for Micromachining Processing (IEEE Jnl. MEMS, 1996) - includes tables of etch rates of numerous metals vs. various wet and dry etchants.
Etch rates for micromachining-Part II (IEEE Jnl. MEMS, 2003) - expanded tables containing resists, dielectrics, metals and semiconductors vs. many wet etch chemicals.
Guide to references on III±V semiconductor chemical etching - exhaustive list of wet etchants for etching various semiconductors, including selective etches.
Transene's Chemical Compatibility Chart provides a useful quick-reference for which Transene etchants attack which materials.
1. As a side-note, Transene provides many pre-mixed solutions that you can order, saving you the time and uncertainty of measuring/mixing such chemicals yourself. Make sure you check with us before ordering so we know how to handle the chemical before it arrives.

Compound Semiconductor Etching

Guide to references on III±V semiconductor chemical etching

Please add any confirmed etches from this reference to the The Master Table of Wet Etching (Include All Materials).

Metal Etching

Silicon etching

Etch rates for micromachining processing

Etch rates for micromachining processing-part II

Please add any confirmed etches from this reference to the The Master Table of Wet Etching (Include All Materials).

Dielectric etching

Organic removal

Gold Plating

Chemi-Mechanical Polishing (CMP)

Example Wet Etching Table

How to use the Master Table of Wet Etching:

When entering a new etch into the table make a row for every etchant used in the solution such that the information can be sorted by etchant. For example, the InP etch HCl:H3PO4(1:3) and H3PO4:HCl(3:1). Likewise, if etch is known to be selective to multiple materials the etch should have a row for each material. For example HCl:H3PO4(1:3) is selective to both InGaAs and InGaAsP.

This multiple entry method may seem laborious for the person entering a new etch, however the power of sorting by selective materials and chemicals in a table with all materials is great.

Material	Etchant	Rate (nm/min)	Anisotropy	Selective to	Selectivity	Ref.	Notes	Confirmed by	Extra column
InP	HCl:H3PO4(1:3)	~1000	Highly	InGaAs	High	Lamponi (p.102)	Example	Jon Doe	Example
InP	HCl:H3PO4(1:3)	~1000	Highly	InGaAsP	High	Lamponi (p.102)	Example	Jon Doe	Example
InP	H3PO4:HCl(3:1)	~1000	Highly	InGaAs	High	Lamponi (p.102)	Example	Jon Doe	Example
InP	H3PO4:HCl(3:1)	~1000	Highly	InGaAsP	High	Lamponi (p.102)	Example	Jon Doe	Example

The Master Table of Wet Etching (Include All Materials)

Use the ↑ ↓ Arrows in the header row to sort the entire table by material, selectivity, etchant etc.

Material	Etchant	Rate (nm/min)	Anisotropy	Selective to	Selectivity	Ref.	Notes	Confirmed by	Extra Notes
InP	HCl:H3PO4 (1:3)	~1000	Highly	InGaAs	High	Lamponi (p.102)	Example	Jon Doe	Example
InP	HCl:H3PO4 (1:3)	~1000	Highly	InGaAsP	High	Lamponi (p.102)	Example	Jon Doe	Example
InP	H3PO4:HCl (3:1)	~1000	Highly	InGaAs	High	Lamponi (p.102)	Example	Jon Doe	Example
InP	H3PO4:HCl (3:1)	~1000	Highly	InGaAsP	High	Lamponi (p.102)	Example	Jon Doe	Example
Al2O3 (ALD Plasma 300C)	Developer: 300MIF	~1.6	None	Most non-Al Materials.	High	Measured in-house	Rate slows with time.	JTB	Example
Al2O3 (ALD Plasma 300C)	Developer: 400K	~2.2	None	Most non-Al Materials.	High	Measured in-house	Rate slows with time.	JTB	Example
Al2O3 (ALD Plasma 300C)	Developer: 400K (1:4)	~1.6	None	Most non-Al Materials.	High	Measured in-house	Rate slows with time.	JTB	Example
Al2O3 (ALD Plasma 300C)	NH4OH:H2O2:H2O (1:2:50)	~<0.5				Measured in-house	Rate slows with time	JTB	Example
Al2O3 (IBD)	HF ("Buffered HF Improved", Transene)	~170	None	Photoresist	High	Measured in-house	May need to increase adhesion with thin SiO2 layer, and 100°C baked HMDS.	Biljana Stamenic	2017-12
Al2O3 (IBD)	Developer: 726 MiF	3.5	None	Most non-Al Materials.		Measured in-house		Demis D. John	2017-11
Al2O3 (AJA#4)	Developer: 300 MiF	4.30	None	Most non-Al Materials.		Measured in-house		Demis D. John	2018-02
SiO2 (PECVD #1)	HF ("Buffered HF Improved", Transene)	~500	None	Photoresist	High	Measured in-house	May need to increase adhesion with 100°C baked HMDS.	Biljana Stamenic	2017
SiO2 (PECVD #2)	HF ("Buffered HF Improved", Transene)	~500	None	Photoresist	High	Measured in-house	May need to increase adhesion with 100°C baked HMDS.	Biljana Stamenic	2017
SiO2 (IBD)	HF ("Buffered HF Improved", Transene)	~350	None	Photoresist	High	Measured in-house		Biljana Stamenic	2016
Si3N4 (PECVD#1)	HF ("Buffered HF Improved", Transene)	85	None	Photoresist	High	Measured in-house		Biljana Stamenic	2018-04
Si3N4 (PECVD#2)	HF ("Buffered HF Improved", Transene)	35–45	None	Photoresist	High	Measured in-house		Biljana Stamenic	2018-05
Si3N4 Low-Stress (PECVD#2)	HF ("Buffered HF Improved", Transene)	35–50	None	Photoresist	High	Measured in-house		Biljana Stamenic	2018-05
Si3N4 (IBD)	HF ("Buffered HF Improved", Transene)	5–15	None	Photoresist	High	Measured in-house		Biljana Stamenic	2014
Ta2O5 (IBD)	HF ("Buffered HF Improved", Transene)	0.4	None	Photoresist	High	Measured in-house		Biljana Stamenic	2016-12
TiO2 (IBD)	HF ("Buffered HF Improved", Transene)	1.0–2.0	None	Photoresist	High	Measured in-house		Biljana Stamenic	2014-12
Si (<100> crystalline)	KOH (45%) @ 87°C	~730	High, Crystallographic	Si3N4 - any PECVD or LPCVD Nitride	High	Measured In-House	Use Covered, Heated vertical bath (Bay 4). Slight Bubbler.	Brian Thibeault	2017

@@ Line 1: / Line 1: @@
-'''See the [https://www.nanotech.ucsb.edu/wiki/index.php/Wet_Etching_Recipes#The_Master_Table_of_Wet_Etching_.28Include_All_Materials.29 Master Wet Etching Table]''' at the bottom of this page for wet-etch rates in various experiments we have tested.
+'''See the [https://wiki.nanotech.ucsb.edu/wiki/index.php/Wet_Etching_Recipes#The_Master_Table_of_Wet_Etching_.28Include_All_Materials.29 Master Wet Etching Table]''' at the bottom of this page for wet-etch rates in various experiments we have tested.
 == References ==
@@ Line 99: / Line 99: @@
 | Al2O3 ''(ALD Plasma 300C)''|| NH4OH:H2O2:H2O (1:2:50) || ~<0.5 ||  ||  |||| Measured in-house || Rate slows with time || JTB || Example
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Al2O3_deposition_.28IBD.29 Al2O3 ''(IBD)'']
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Al2O3_deposition_.28IBD.29 Al2O3 ''(IBD)'']
 |HF ("Buffered HF Improved", Transene)
 |~170
@@ Line 110: / Line 110: @@
 |2017-12
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Al2O3_deposition_.28IBD.29 Al2O3 ''(IBD)'']
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Al2O3_deposition_.28IBD.29 Al2O3 ''(IBD)'']
 |Developer: 726 MiF
 |3.5
@@ Line 121: / Line 121: @@
 |2017-11
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Al2O3_Deposition_.28Sputter_4.29 Al2O3 ''(AJA#4)'']
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Al2O3_Deposition_.28Sputter_4.29 Al2O3 ''(AJA#4)'']
 |Developer: 300 MiF
 |4.30
@@ Line 132: / Line 132: @@
 |2018-02
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#SiO2_deposition_.28PECVD_.231.29 SiO2 ''(PECVD #1)'']
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#SiO2_deposition_.28PECVD_.231.29 SiO2 ''(PECVD #1)'']
 |HF ("Buffered HF Improved", Transene)
 |~500
@@ Line 143: / Line 143: @@
 |2017
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#SiO2_deposition_.28PECVD_.232.29 SiO2 ''(PECVD #2)'']
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#SiO2_deposition_.28PECVD_.232.29 SiO2 ''(PECVD #2)'']
 |HF ("Buffered HF Improved", Transene)
 |~500
@@ Line 154: / Line 154: @@
 |2017
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#SiO2_deposition_.28IBD.29 SiO2 (IBD)]
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#SiO2_deposition_.28IBD.29 SiO2 (IBD)]
 |HF ("Buffered HF Improved", Transene)
 |~350
@@ Line 165: / Line 165: @@
 |2016
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#SiN_deposition_.28PECVD_.231.29 Si3N4 (PECVD#1)]
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#SiN_deposition_.28PECVD_.231.29 Si3N4 (PECVD#1)]
 |HF ("Buffered HF Improved", Transene)
 |85
@@ Line 176: / Line 176: @@
 |2018-04
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#SiN_deposition_.28PECVD_.232.29 Si3N4 (PECVD#2)]
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#SiN_deposition_.28PECVD_.232.29 Si3N4 (PECVD#2)]
 |HF ("Buffered HF Improved", Transene)
 |35–45
@@ Line 187: / Line 187: @@
 |2018-05
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#Low-Stress_SiN_deposition_.28PECVD_.232.29 Si3N4 Low-Stress (PECVD#2)]
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/PECVD_Recipes#Low-Stress_SiN_deposition_.28PECVD_.232.29 Si3N4 Low-Stress (PECVD#2)]
 |HF ("Buffered HF Improved", Transene)
 |35–50
@@ Line 198: / Line 198: @@
 |2018-05
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Si3N4_deposition_.28IBD.29 Si3N4 (IBD)]
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Si3N4_deposition_.28IBD.29 Si3N4 (IBD)]
 |HF ("Buffered HF Improved", Transene)
 |5–15
@@ Line 209: / Line 209: @@
 |2014
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Ta2O5_deposition_.28IBD.29 Ta2O5 (IBD)]
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#Ta2O5_deposition_.28IBD.29 Ta2O5 (IBD)]
 |HF ("Buffered HF Improved", Transene)
 |0.4
@@ Line 220: / Line 220: @@
 |2016-12
 |-
-|[https://www.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#TiO2_deposition_.28IBD.29 TiO2 (IBD)]
+|[https://wiki.nanotech.ucsb.edu/wiki/index.php/Sputtering_Recipes#TiO2_deposition_.28IBD.29 TiO2 (IBD)]
 |HF ("Buffered HF Improved", Transene)
 |1.0–2.0