Specific Process Knowledge/Thin film deposition/thermalevaporator: Difference between revisions

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[[Category: Equipment|Thin film]]
[[Category: Equipment|Thin film]]
[[Category: Thin Film Deposition|Alcatel]]
[[Category: Thin Film Deposition|Thermal Evaporator]]




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[[Image:IMG_2592_edit.jpg|300x300px|thumb| Positioned in cleanroom A-1.]]
[[Image:IMG_2592_edit.jpg|300x300px|thumb| Positioned in cleanroom A-1.]]


The main purpose for the thermal evaporator is to deposit Al for removing charging of the restsit when doing EBL on isolerede substrate.
The main purpose of the thermal evaporator is to deposit Al for removing charging of the resist when doing EBL on isolating substrate.
   
   
It is no only usable for Al deposition. The thermal evaporator have room for two boats and there by the possibility to make thinfilms of two different metals. At the moment not that many metals have been test and made a recipe for. Right now is is only Al and Ag that can be used.   
It is not only usable for Al deposition. The thermal evaporator has room for two evaporation sources and thereby the possibility to make thin films of two different metals. At the moment not that many metals have been tested, so right now only Al and Ag can be evaporated. Cr can also be evapoarated (with very good results), but require a major change in hardware configuration. We have attempted to evaporate Au and Zn but these are not standard processesIf you would like to deposit these or other metals, please talk to the Thin Film group.
 
Compared to the [[Specific Process Knowledge/Thin film deposition/Wordentec|Wordentec]], the thermal evaporator is quicker to use if you only need to deposit on one wafer or on small samples, as it only takes about 15 minutes to pump down the chamber. You can also deposit thicker layers because the throw distance from source to sample is shorter, so the material use is more efficient: In the thermal evaporator, you get up to 200 nm per metal pellet, whereas in the Wordentec you get about 15 nm per pellet. However, the thickness uniformity is better for large samples in the Wordentec also because of the longer distance from source to sample.


So if you want a quick deposition process and/or a relatively thick metal layer, and your samples are small or the thickness uniformity is not critical, then the Thermal Evaporator is a very good choice for you. If you need to deposit on many wafers or you need a more constant layer uniformity across a full 4" or 6" wafer, then the Wordentec is best.




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==Process information==
==Process information==
====Materials for thermal evaporator evaporation====
====Materials evaporated in the Lesker Thermal Evaporator====


*[[Specific Process Knowledge/Thin film deposition/Deposition of Aluminium|Aluminium]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Aluminium/Thermal deposition of Al|Aluminium]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Silver|Silver]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Silver|Silver]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Chromium/Thermal evaporation of Cr in Thermal evaporator|Chromium]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Germanium/Thermal Ge evaporation Thermal Evaporator|Germanium]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Gold/Resistive thermal evaporation of Au in Thermal Evaporator|Gold]]
*[[Specific Process Knowledge/Thin film deposition//Deposition of Copper/Resistive thermal evaporation of Copper|Copper]]
*([[Specific Process Knowledge/Thin film deposition/Deposition of Zinc|Zinc]] - we don't like to evaporate this material)
We can also evaporate gold in this evaporator and can develop processes for other materials if requested.


==Equipment performance and process related parameters Alcatel==
==Equipment performance and process related parameters==


{| border="2" cellspacing="0" cellpadding="10"  
{| border="2" cellspacing="0" cellpadding="10"  
|-
|-
!style="background:silver; color:black;" align="left"|Purpose  
!style="background:silver; color:black;" align="left"|Purpose  
|style="background:LightGrey; color:black"|Deposition of metals and silicon ||style="background:WhiteSmoke; color:black"|
|style="background:LightGrey; color:black"|Deposition of metals ||style="background:WhiteSmoke; color:black"|
*Thermal evaporation of metals
*Thermal evaporation of metals
|-
|-
!style="background:silver; color:black" align="left" valign="top" rowspan="2"|Performance
!style="background:silver; color:black" align="left" valign="top" rowspan="4"|Performance
|style="background:LightGrey; color:black"|Film thickness||style="background:WhiteSmoke; color:black"|
|style="background:LightGrey; color:black"|Film thickness||style="background:WhiteSmoke; color:black"|
*10Å - 1µm* (for some materials)
*10Å - 1µm (Al and Ag)
*up to 80 nm (Cr)
|-
|-
|style="background:LightGrey; color:black"|Deposition rate
|style="background:LightGrey; color:black"|Deposition rate
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
*0.5 Å/s - 5 Å/s (material dependens)
*0.5-2 Å/s (Al), 5 Å/s (Ag), 1 Å/s (Cr)
*In general, 0.5-10 Å/s is possible
*We need to develop a new process for each rate
|-
|style="background:LightGrey; color:black"|Thickness uniformity
|style="background:WhiteSmoke; color:black"|
*approx. 13 % variation on a 4" wafer with 100 nm Al *
*approx. 23 % variation on a 4" wafer with 100 nm Ag *
*approx. 10 % variation on a 6" wafer with 100 nm Cr *
|-
|style="background:LightGrey; color:black"|Pumpdown time
|style="background:WhiteSmoke; color:black"|
*about 15 min
|-
|-
!style="background:silver; color:black" align="left" valign="top" rowspan="2"|Process parameter range
!style="background:silver; color:black" align="left" valign="top" rowspan="2"|Process parameter range
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|style="background:LightGrey; color:black"|Process pressure
|style="background:LightGrey; color:black"|Process pressure
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* Low than 4*10<sup>-6</sup> mbar
* Below 4*10<sup>-6</sup> mbar
|-
|-
!style="background:silver; color:black" align="left" valign="top" rowspan="3"|Substrates
!style="background:silver; color:black" align="left" valign="top" rowspan="3"|Substrates
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|-  
|-  
|}
|}
 
''*'' ''The variation is defined as (Max-Min)/Average for the various points measured on the wafer. The max. point was around the center and the min. somewhere along the edge. The exact location of the maximum thickness depends how the sample is placed relative to the point of maximum material flux. Measurement by Rebecca Ettlinger, Nov. 2018.''
'''*''' ''For thicknesses above 200 nm permission is requested.''

Latest revision as of 15:11, 9 February 2024

Feedback to this page: click here

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


Thermal evaporator- A system for deposition of metals

Positioned in cleanroom A-1.

The main purpose of the thermal evaporator is to deposit Al for removing charging of the resist when doing EBL on isolating substrate.

It is not only usable for Al deposition. The thermal evaporator has room for two evaporation sources and thereby the possibility to make thin films of two different metals. At the moment not that many metals have been tested, so right now only Al and Ag can be evaporated. Cr can also be evapoarated (with very good results), but require a major change in hardware configuration. We have attempted to evaporate Au and Zn but these are not standard processes. If you would like to deposit these or other metals, please talk to the Thin Film group.

Compared to the Wordentec, the thermal evaporator is quicker to use if you only need to deposit on one wafer or on small samples, as it only takes about 15 minutes to pump down the chamber. You can also deposit thicker layers because the throw distance from source to sample is shorter, so the material use is more efficient: In the thermal evaporator, you get up to 200 nm per metal pellet, whereas in the Wordentec you get about 15 nm per pellet. However, the thickness uniformity is better for large samples in the Wordentec also because of the longer distance from source to sample.

So if you want a quick deposition process and/or a relatively thick metal layer, and your samples are small or the thickness uniformity is not critical, then the Thermal Evaporator is a very good choice for you. If you need to deposit on many wafers or you need a more constant layer uniformity across a full 4" or 6" wafer, then the Wordentec is best.


The user manual, APV, technical information and contact information can be found in LabManager:

Thermal Evaporator in LabManager


Process information

Materials evaporated in the Lesker Thermal Evaporator

We can also evaporate gold in this evaporator and can develop processes for other materials if requested.

Equipment performance and process related parameters

Purpose Deposition of metals
  • Thermal evaporation of metals
Performance Film thickness
  • 10Å - 1µm (Al and Ag)
  • up to 80 nm (Cr)
Deposition rate
  • 0.5-2 Å/s (Al), 5 Å/s (Ag), 1 Å/s (Cr)
  • In general, 0.5-10 Å/s is possible
  • We need to develop a new process for each rate
Thickness uniformity
  • approx. 13 % variation on a 4" wafer with 100 nm Al *
  • approx. 23 % variation on a 4" wafer with 100 nm Ag *
  • approx. 10 % variation on a 6" wafer with 100 nm Cr *
Pumpdown time
  • about 15 min
Process parameter range Process Temperature
  • Approximately room temperature
Process pressure
  • Below 4*10-6 mbar
Substrates Batch size
  • Up to 8" wafer
  • Or several smaller pieces
  • Deposition on one side of the substrate
Substrate material allowed
  • Silicon wafers
  • Quartz wafers
  • Pyrex wafers
Material allowed on the substrate
  • Silicon oxide
  • Silicon (oxy)nitride
  • Photoresist
  • PMMA
  • Mylar
  • Metals

* The variation is defined as (Max-Min)/Average for the various points measured on the wafer. The max. point was around the center and the min. somewhere along the edge. The exact location of the maximum thickness depends how the sample is placed relative to the point of maximum material flux. Measurement by Rebecca Ettlinger, Nov. 2018.