Specific Process Knowledge/Thin film deposition/Deposition of Gold: Difference between revisions

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<center><span style="background:#87CEEB">4th Level - Comparison</span></center>
'''Feedback to this page''': '''[mailto:labadviser@nanolab.dtu.dk?Subject=Feed%20back%20from%20page%20http://labadviser.nanolab.dtu.dk/index.php/Specific_Process_Knowledge/Thin_film_deposition/Deposition_of_Gold click here]'''
'''Feedback to this page''': '''[mailto:labadviser@danchip.dtu.dk?Subject=Feed%20back%20from%20page%20http://labadviser.danchip.dtu.dk/index.php/Specific_Process_Knowledge/Etch/RIE_(Reactive_Ion_Etch) click here]'''


Gold can be deposited by e-beam evaporation or sputtering. In the chart below you can compare the different deposition equipment.
<i> Unless otherwise stated, this page is written by <b>DTU Nanolab internal</b></i>


Gold can be deposited by e-beam evaporation or sputtering. In the chart below you can compare the different deposition equipment. We also describe the temperature rise on the wafer during gold deposition, the adhesion layers that can be used for gold deposition, the roughness of gold deposited in the Wordentec, and issues with particulates on the gold films in the Temescal and the Wordentec.
== Au deposition ==
Below you can compare the different equipment that allows Au deposition.


{| border="1" cellspacing="0" cellpadding="4"  
{| border="1" cellspacing="0" cellpadding="4"  
Line 9: Line 12:
|-style="background:silver; color:black"
|-style="background:silver; color:black"
!  
!  
! E-beam evaporation ([[Specific Process Knowledge/Thin film deposition/Alcatel|Alcatel]])
! E-beam evaporation ([[Specific Process Knowledge/Thin film deposition/Temescal|E-beam evaporator (Temescal)]] and [[Specific Process Knowledge/Thin film deposition/10-pocket e-beam evaporator|E-beam evaporator (10-pockets)]])
! E-beam evaporation ([[Specific Process Knowledge/Thin film deposition/Wordentec|Wordentec]])
! E-beam evaporation ([[Specific Process Knowledge/Thin film deposition/Wordentec|Wordentec]])
! Resistive thermal evaporation ([[Specific Process Knowledge/Thin film deposition/thermalevaporator|Thermal Evaporator]])
! Sputter ([[Specific Process Knowledge/Thin film deposition/Lesker|Lesker]])
! Sputter ([[Specific Process Knowledge/Thin film deposition/Lesker|Lesker]])
! E-beam evaporation ([[Specific Process Knowledge/Thin film deposition/Physimeca|Physimeca]])
! Sputter ([[Specific Process Knowledge/Thin film deposition/Cluster-based multi-chamber high vacuum sputtering deposition system|Sputter-system Metal-Oxide (PC1) and Sputter-system Metal-Nitride (PC3)]])
! Sputter coater [[Specific Process Knowledge/Thin film deposition/Sputter coater#The_Hummer_Sputter_coater|Hummer]]
! Sputter coater [[Specific Process Knowledge/Thin film deposition/Sputter coater#Sputter coater 03|(Sputter coater 03)]]
! Sputter coater [[Specific Process Knowledge/Thin film deposition/Sputter coater#The_Balzer_Sputter_coater|Balzer]]
! Sputter coater [[Specific Process Knowledge/Thin film deposition/Sputter coater#Sputter coater 04|(Sputter coater 04)]]
|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
! General description
! General description
| E-beam deposition of Au
| E-beam deposition of Au
| E-beam deposition of Au
| E-beam deposition of Au
| Resistive thermal deposition of Au
| Sputter deposition of Au
| Sputter deposition of Au
| Sputter deposition of Au
| E-beam deposition of Au
| Sputter deposition of Au
| Sputter deposition of Au
| Sputter deposition of Au
| Sputter deposition of Au
Line 26: Line 31:
|-style="background:LightGrey; color:black"
|-style="background:LightGrey; color:black"
! Pre-clean
! Pre-clean
|Ar ion etch (only in E-beam evaporator Temescal)
|
|
|RF Ar clean
|RF Ar clean
|RF Ar clean
|RF Ar clean
|RF Ar clean
|
|
|
|
|
|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
! Layer thickness
! Layer thickness
|10 Å to 5000Å*  
|10 Å to 1 µm *
|10 Å to 5000Å*
|10 Å to 1 µm *
|10 Å to
|10 Å to 200 nm
|10Å to about 3000Å*
|10 Å to 5000 Å **
|
|10 Å to 5000 Å **
|
| very thin, few nm range
| very thin, few nm range


|-
|-
|-style="background:LightGrey; color:black"
|-style="background:LightGrey; color:black"
! Deposition rate
! Deposition rate
|2 Å/s to 10 Å/s
|0.5-10 Å/s (in 10-pocket machine only up to 5 Å/s as material is deposited from a liner)
|1 Å/s to 10 Å/s
|1-10 Å/s
|
|1 Å/s (can be adjusted to around 5Å/s)
|From 5 Å/s up to 10Å/s
|Depends on process parameters, 1-10 Å/s  
|Depends on process parameters
|Not measured
|Not measured
|Not measured
|Not measured
Line 58: Line 64:
! Batch size
! Batch size
|
|
*Up to 1x4" wafers
*Up to 4x6" wafers or
*smaller pieces
*Up to 3x8" wafers (ask for special holder)
*many smaller pieces
|
|
*24x2" wafers or  
*24x2" wafers or  
*6x4" wafers or
*6x4" wafers or
*6x6" wafers
*6x6" wafers
|
*4x2" wafers or
*3x4" wafers or
*1x6" wafer
*1x8" wafer
*many smaller pieces
|
|
*Pieces or
*Pieces or
Line 69: Line 82:
*1x6" wafer
*1x6" wafer
|
|
*1x 2" wafer or
*Up to 10x6" or 4" wafers
*1x 4" wafers or
*Many small pieces  
*Several smaller pieces  
|
|
*Several smaller samples
*1x4" wafer
*1x4" wafer
*Several smaller samples
|
|
*1 large sample (< 4" wafer)
*Several smaller samples
*Several smaller samples
*1x4" wafer


|-
|-
Line 84: Line 96:
!Allowed materials
!Allowed materials


|
*See the [http://labmanager.dtu.dk/function.php?module=XcMachineaction&view=edit&MachID=429 cross-contamination sheet]
|
|
* Silicon oxide  
* Silicon oxide  
Line 93: Line 108:
* Metals  
* Metals  
|
|
* Silicon oxide
* Almost any as long as it does not outgas - see cross-contamination sheets in Labmanager
* Silicon (oxy)nitride
* Photoresist
* PMMA
* Mylar
* SU-8
* Metals
|
|
* Silicon
* Silicon
Line 112: Line 121:
* Carbon
* Carbon
|
|
* III-V materials
* Almost any as long as it does not outgas - see cross-contamination sheets in Labmanager
* Silicon wafers
|
* Quartz wafers
* All samples allowed in the SEM Supra 1
* Pyrex wafers
|
|.
* All samples allowed in the SEM Supra 2 or 3
|.
 


|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
! Comment
! Comment
|
|
* For thicknesses above 200 nm permission is required
* For thicknesses above 600 nm permission is required
* An adhesion layer (of Cr or Ti) is recommended under Au.
* Takes approx. 20 min to pump down.
|
* Takes approx. 1 hour to pump down.
|
*Make sure that all pellets are melted beforehand
|
|
* For thicknesses above 200 nm permission is required
*Takes approx. 10 minutes to load and transfer sample
* An adhesion layer (of Cr or Ti) is recommended under Au.
|
|
* Takes approx. 12 minutes to load and transfer samples
|
|
* Used for gold sputter coating of samples before SEM inspection
* Very fast.
|
* Used for gold sputter coating of samples before SEM inspection
*Very fast.
|-
|}


|Used to gold sputter coating of 
samples mainly before SEM characterization
|Used to gold sputter coating of
samples mainly before SEM characterization


'''*'''  ''For thicknesses above 600 nm write to metal@nanolab.dtu.dk to ensure that there will be enough material in the machine.''
'''**'''  ''For thicknesses above 200 nm write to metal@nanolab.dtu.dk to ensure that there will be enough material in the machine.''
== Studies of Au deposition processes in the Wordentec==
[[/Roughness of Au|Roughness of Au layers]] - ''Roughness of Au layers deposited in the Wordentec''
===Wafer temperature===
The wafer temperature during e-beam deposition of 200 nm Au on six wafers has been measured using thermal labels on the backside of the wafers. The following results were obtained:
{| border="1" cellspacing="0" cellpadding="2"
! Wafer
! Temperature [C]
|-
|1
|48
|-
|2
|60
|-
|3
|65
|-
|4
|71
|-
|5
|71
|-
|6
|77
|-
|-
|}
|}
The temperatures are accurate within approximately +/- 3C and probably underestimating the actual wafer temperature slightly. It is observed that the wafer temperature increases with each wafer, thus if wafer temperature is of concern it is advised to reduce the number of wafers per run.


== Resistive thermal evaporation of Au ==


'''*'''  ''For thicknesses above 200 nm permission from ThinFilm group (thinfilm@danchip.dtu.dk) is required.''
* [[Specific Process Knowledge/Thin film deposition/Deposition of Gold/Resistive thermal evaporation of Au in Thermal Evaporator|Resistive thermal evaporation of Au in Thermal Evaporator]]


== Adhesion of Au on Si ==
== Adhesion of Au on Si ==
[[/Adhesion of Au|Adhesion of Au layers]]
The adhesion of gold on Silicon or Silicon with native oxide is not very good. The Si substrate is often deposited an adhesion layer before the gold deposition. A few nm of Chromium or Titanium works well and they react with the Oxygen of Silicon oxide and present a metallic bond with gold. You can also use polymer or organosilane adhesion layers as exemplified by the work in the next section.


For Cr and Ti adhesion layers, a 5 nm to 10 nm thick layer of Cr or Ti is commonly used and it is important to deposit Cr or Ti and then immediately Au. If the vacuum chamber is opened in between, the surface of Cr or Ti will get oxidized and that will give a poor adhesion. If a gold layer needs to be deposited directly on Silicon, then native oxide has to be removed by deep in diluted HF and immediately load the evaporation chamber. And after the deposition, the wafer has to be heated op to get some Au-Si diffusion which improves the adhesion. 


== Studies of Au deposition processes ==
*[[/Adhesion layers|Read more about Ti and Cr adhesion layers]].
[[/Roughness of Au|Roughness of Au layers]] - ''Roughness of Au layers deposited with different equipment and settings''
 
Below you can read about using an organosilane adhesion layer.
 
== Thin Au layer using APTMS adhesion layer and sputter system Lesker ==
For depositing very thin, down to 6nm continuous Au layers on Si/SiO<sub>2</sub> substrates. Works also with ALD deposited Al<sub>2</sub>O<sub>3</sub> and TiO<sub>2</sub> as substrate.
 
Adhesion promoter: aminopropyltrimethoxysilane (APTMS). MSDS [[media:MSDS_APTMS.pdf|here]]. <br/>
Adhesion promoter deposition: 3h immersion in 95%IPA, 2.5% H<sub>2</sub>O, 2.5% APTMS.
 
''NOTE: the APTMS layer is degrading quickly in atmosphere, so deposit it as close to the Au deposition as possible.''
 
Lesker deposition parameters:
{| border="1" cellspacing="0" cellpadding="2"
! Gun #
! Power [W]
! Ramp rate [W/s]
! Pressure [mtorr]
! Atmosphere
! Deposition rate [nm/s]
|-
|2
|300
|5
|3
|Ar
|1
|}
 
''NOTE: As a general rule, the lower the pressure and higher the power (i.e. higher the deposition rate), the better.''
 
Film characteristics (5-10 wafers for each thickness):
{| border="1" cellspacing="0" cellpadding="2"
! Thickness [nm]
! Roughness min [nm]
! Roughness max [nm]
|-
|6
|0.25
|0.4
|-
|10
|0.3
|0.5
|-
|24
|0.3
|0.5
|}
 
''NOTE: After depositing 10 layers of 10nm each, one on top of each other, the roughness increased to 0.8nm RMS''
 
Work done by Johneph Sukham (@ DTU Fotonik) and Radu Malureanu (@ DTU Fotonik and DTU Nanolab) in 2016-2017.
 
==Particulates in e-beam evaporated films==
[[File:particulates au film.png|right|thumb|upright=2|Alt=SEM image of a film with droplets ranging in size from a few hundred nanometers to about 1.5 microns.|Au droplets on an Au film (image by Evgeniy Shkondin, Au identified by EDX).]]
 
We have found that the amount of particulates on the e-beam evaporated films depends on the deposition parameters. Specifically for gold it is hard to avoid tiny gold droplets on the films, but they can be minimized with careful attention to the sweep parameters, cleanliness of the target, etc.
 
The droplets appear to be inconsequential for many users, for instance if the Au layer is simply used as an electrical contact. However, for some users it is very important, for instance when the exact resistivity of the Au layer is critical.
 
 
You can read more about this issue [[Specific_Process_Knowledge/Thin_film deposition/Temescal/Particulates_in_Temescal_Au_films|here]].
 
<br clear="all" />
 
==Quality control of e-beam evaporated TiAu films==
 
{| border="1" cellspacing="2" cellpadding="2" colspan="3"
|bgcolor="#98FB98" |'''Quality control (QC) for the Temescal'''
|-
|
*[http://labmanager.dtu.dk/d4Show.php?id=5862&mach=429 QC procedure for the Temescal]<br>
*[https://labmanager.dtu.dk/view_binary.php?type=data&mach=429 The newest QC data for the Temescal]<br>
 
{| {{table}}
| align="center" |
{| border="1" cellspacing="1" cellpadding="2"  align="center" style="width:400px"
 
! QC Recipe:
! Standard recipes/TiAu or Cr/Au
|-
|Deposition rate
|was at 10 Å/s (change to 2 Å/s from October 2022 as it gives less particles)
|-
|Thickness
|10 nm / 90 nm
|-
|Pressure
|Below 1*10<sup>-6</sup> mbar
|-
|}
| align="center" valign="top"|
{| border="2" cellspacing="1" cellpadding="2" align="center" style="width:440px"
!QC limits
!Temescal
|-
|Deposition rate deviation
|± 20 %
|-
|Measured average thickness
|± 10 %
|-
|Thickness deviation across a 4" wafer
|± 5 %
|-
|}
|-
|}
Thickness is measured in 5 points with a stylus profiler. <br>
Additionally we examine the newly deposited films for particles using the particle scanner (if available, otherwise we use the Jenatech microscope in darkfield mode) and we monitor the sheet resistance of the Ti/Au or Cr/Au films.
|}
 
 
{| border="1" cellspacing="2" cellpadding="2" colspan="3"
|bgcolor="#98FB98" |'''Quality control (QC) for Wordentec'''
|-
|
*[http://labmanager.dtu.dk/d4Show.php?id=3736&mach=167 QC procedure for Wordentec]<br>
*[https://labmanager.dtu.dk/view_binary.php?type=data&mach=167 The newest QC data for Wordentec]<br>
 
{| {{table}}
| align="center" |
{| border="1" cellspacing="1" cellpadding="2"  align="center" style="width:300px"
 
! QC Recipe:
! Process 13
|-
|Deposition rate
|10 Å/s
|-
|Thickness
|10 nm / 90 nm
|-
|Pressure
|Below 4*10<sup>-6</sup> mbar
|-
|}
| align="center" valign="top"|
{| border="2" cellspacing="1" cellpadding="2" align="center" style="width:440px"
!QC limits
!Wordentec
|-
|Measured average thickness (Å)
|± 10 %
|-
|Lowest accepted deposition rate (Å/s)
|6 Å/s
|-
|}
|-
|}
Thickness is measured in 5 points with a stylus profiler.
|}

Latest revision as of 16:35, 7 February 2024

Feedback to this page: click here

Unless otherwise stated, this page is written by DTU Nanolab internal

Gold can be deposited by e-beam evaporation or sputtering. In the chart below you can compare the different deposition equipment. We also describe the temperature rise on the wafer during gold deposition, the adhesion layers that can be used for gold deposition, the roughness of gold deposited in the Wordentec, and issues with particulates on the gold films in the Temescal and the Wordentec.

Au deposition

Below you can compare the different equipment that allows Au deposition.

E-beam evaporation (E-beam evaporator (Temescal) and E-beam evaporator (10-pockets)) E-beam evaporation (Wordentec) Resistive thermal evaporation (Thermal Evaporator) Sputter (Lesker) Sputter (Sputter-system Metal-Oxide (PC1) and Sputter-system Metal-Nitride (PC3)) Sputter coater (Sputter coater 03) Sputter coater (Sputter coater 04)
General description E-beam deposition of Au E-beam deposition of Au Resistive thermal deposition of Au Sputter deposition of Au Sputter deposition of Au Sputter deposition of Au Sputter deposition of Au
Pre-clean Ar ion etch (only in E-beam evaporator Temescal) RF Ar clean RF Ar clean
Layer thickness 10 Å to 1 µm * 10 Å to 1 µm * 10 Å to 200 nm 10 Å to 5000 Å ** 10 Å to 5000 Å ** very thin, few nm range very thin, few nm range
Deposition rate 0.5-10 Å/s (in 10-pocket machine only up to 5 Å/s as material is deposited from a liner) 1-10 Å/s 1 Å/s (can be adjusted to around 5Å/s) Depends on process parameters, 1-10 Å/s Depends on process parameters Not measured Not measured
Batch size
  • Up to 4x6" wafers or
  • Up to 3x8" wafers (ask for special holder)
  • many smaller pieces
  • 24x2" wafers or
  • 6x4" wafers or
  • 6x6" wafers
  • 4x2" wafers or
  • 3x4" wafers or
  • 1x6" wafer
  • 1x8" wafer
  • many smaller pieces
  • Pieces or
  • 1x4" wafer or
  • 1x6" wafer
  • Up to 10x6" or 4" wafers
  • Many small pieces
  • Several smaller samples
  • 1x4" wafer
  • Several smaller samples
  • 1x4" wafer
Allowed materials
  • Silicon oxide
  • Silicon (oxy)nitride
  • Photoresist
  • PMMA
  • Mylar
  • SU-8
  • Metals
  • Almost any as long as it does not outgas - see cross-contamination sheets in Labmanager
  • Silicon
  • Silicon oxide
  • Silicon nitride
  • Silicon (oxy)nitride
  • Photoresist
  • PMMA
  • Mylar
  • SU-8
  • Metals
  • Carbon
  • Almost any as long as it does not outgas - see cross-contamination sheets in Labmanager
  • All samples allowed in the SEM Supra 1
  • All samples allowed in the SEM Supra 2 or 3
Comment
  • For thicknesses above 600 nm permission is required
  • Takes approx. 20 min to pump down.
  • Takes approx. 1 hour to pump down.
  • Make sure that all pellets are melted beforehand
  • Takes approx. 10 minutes to load and transfer sample
  • Takes approx. 12 minutes to load and transfer samples
  • Used for gold sputter coating of samples before SEM inspection
  • Very fast.
  • Used for gold sputter coating of samples before SEM inspection
  • Very fast.


* For thicknesses above 600 nm write to metal@nanolab.dtu.dk to ensure that there will be enough material in the machine.

** For thicknesses above 200 nm write to metal@nanolab.dtu.dk to ensure that there will be enough material in the machine.

Studies of Au deposition processes in the Wordentec

Roughness of Au layers - Roughness of Au layers deposited in the Wordentec

Wafer temperature

The wafer temperature during e-beam deposition of 200 nm Au on six wafers has been measured using thermal labels on the backside of the wafers. The following results were obtained:

Wafer Temperature [C]
1 48
2 60
3 65
4 71
5 71
6 77

The temperatures are accurate within approximately +/- 3C and probably underestimating the actual wafer temperature slightly. It is observed that the wafer temperature increases with each wafer, thus if wafer temperature is of concern it is advised to reduce the number of wafers per run.

Resistive thermal evaporation of Au

Adhesion of Au on Si

The adhesion of gold on Silicon or Silicon with native oxide is not very good. The Si substrate is often deposited an adhesion layer before the gold deposition. A few nm of Chromium or Titanium works well and they react with the Oxygen of Silicon oxide and present a metallic bond with gold. You can also use polymer or organosilane adhesion layers as exemplified by the work in the next section.

For Cr and Ti adhesion layers, a 5 nm to 10 nm thick layer of Cr or Ti is commonly used and it is important to deposit Cr or Ti and then immediately Au. If the vacuum chamber is opened in between, the surface of Cr or Ti will get oxidized and that will give a poor adhesion. If a gold layer needs to be deposited directly on Silicon, then native oxide has to be removed by deep in diluted HF and immediately load the evaporation chamber. And after the deposition, the wafer has to be heated op to get some Au-Si diffusion which improves the adhesion.

Below you can read about using an organosilane adhesion layer.

Thin Au layer using APTMS adhesion layer and sputter system Lesker

For depositing very thin, down to 6nm continuous Au layers on Si/SiO2 substrates. Works also with ALD deposited Al2O3 and TiO2 as substrate.

Adhesion promoter: aminopropyltrimethoxysilane (APTMS). MSDS here.
Adhesion promoter deposition: 3h immersion in 95%IPA, 2.5% H2O, 2.5% APTMS.

NOTE: the APTMS layer is degrading quickly in atmosphere, so deposit it as close to the Au deposition as possible.

Lesker deposition parameters:

Gun # Power [W] Ramp rate [W/s] Pressure [mtorr] Atmosphere Deposition rate [nm/s]
2 300 5 3 Ar 1

NOTE: As a general rule, the lower the pressure and higher the power (i.e. higher the deposition rate), the better.

Film characteristics (5-10 wafers for each thickness):

Thickness [nm] Roughness min [nm] Roughness max [nm]
6 0.25 0.4
10 0.3 0.5
24 0.3 0.5

NOTE: After depositing 10 layers of 10nm each, one on top of each other, the roughness increased to 0.8nm RMS

Work done by Johneph Sukham (@ DTU Fotonik) and Radu Malureanu (@ DTU Fotonik and DTU Nanolab) in 2016-2017.

Particulates in e-beam evaporated films

Au droplets on an Au film (image by Evgeniy Shkondin, Au identified by EDX).

We have found that the amount of particulates on the e-beam evaporated films depends on the deposition parameters. Specifically for gold it is hard to avoid tiny gold droplets on the films, but they can be minimized with careful attention to the sweep parameters, cleanliness of the target, etc.

The droplets appear to be inconsequential for many users, for instance if the Au layer is simply used as an electrical contact. However, for some users it is very important, for instance when the exact resistivity of the Au layer is critical.


You can read more about this issue here.


Quality control of e-beam evaporated TiAu films

Quality control (QC) for the Temescal
QC Recipe: Standard recipes/TiAu or Cr/Au
Deposition rate was at 10 Å/s (change to 2 Å/s from October 2022 as it gives less particles)
Thickness 10 nm / 90 nm
Pressure Below 1*10-6 mbar
QC limits Temescal
Deposition rate deviation ± 20 %
Measured average thickness ± 10 %
Thickness deviation across a 4" wafer ± 5 %

Thickness is measured in 5 points with a stylus profiler.
Additionally we examine the newly deposited films for particles using the particle scanner (if available, otherwise we use the Jenatech microscope in darkfield mode) and we monitor the sheet resistance of the Ti/Au or Cr/Au films.


Quality control (QC) for Wordentec
QC Recipe: Process 13
Deposition rate 10 Å/s
Thickness 10 nm / 90 nm
Pressure Below 4*10-6 mbar
QC limits Wordentec
Measured average thickness (Å) ± 10 %
Lowest accepted deposition rate (Å/s) 6 Å/s

Thickness is measured in 5 points with a stylus profiler.