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

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== LESKER Sputter Tool==
The purpose of the sputter is to deposit magnetic metals and dielectrica on a single 4" or 6" wafer at a time.
It can be a problem to take wafers from the sputter and into the other machines in the cleanroom, since it is not very clean. In principle the sputter should be the last step before you take your wafers out of the cleanroom. If you need to take process your wafers further please contact the PVD group so they can help you.
Lift off should never be done in the normal lift off bath in RR4 it should always be done in the dedicated lift off bath opposite the sputter.
====Materials for sputtering====
*[[Specific Process Knowledge/Thin film deposition/Deposition of Gold|Gold (Au)]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Nickel|Nickel (Ni)]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Silver|Silver (Ag)]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Silicon|Silicon (Si)]]
*Iron (Fe)
Contcat the pvd-group if you have special needs (pvd@danchip.dtu.dk).
==Overview of the performance of Alcatel and some process related parameters==
{| border="2" cellspacing="0" cellpadding="10"
|-
!style="background:silver; color:black;" align="left"|Purpose
|style="background:LightGrey; color:black"|Deposition of magnetic metals and dielectrica ||style="background:WhiteSmoke; color:black"|
*Sputtering of magnetic metals and Silicon
|-
!style="background:silver; color:black" align="left" valign="top" rowspan="2"|Performance
|style="background:LightGrey; color:black"|Film thickness||style="background:WhiteSmoke; color:black"|
*
|-
|style="background:LightGrey; color:black"|Deposition rates
|style="background:WhiteSmoke; color:black"|
*
|-
!style="background:silver; color:black" align="left" valign="top" rowspan="3"|Process parameter range
|style="background:LightGrey; color:black"|Process Temperature
|style="background:WhiteSmoke; color:black"|
*100-200<math>^o</math>C
|-
|style="background:LightGrey; color:black"|Process pressure
|style="background:WhiteSmoke; color:black"|
*3-5 mTorr
|-
|style="background:LightGrey; color:black"|Process Gases
|style="background:WhiteSmoke; color:black"|
*Ar
*N<math>_2</math>
*O<math>_2</math>
|-
!style="background:silver; color:black" align="left" valign="top" rowspan="3"|Substrates
|style="background:LightGrey; color:black"|Batch size
|style="background:WhiteSmoke; color:black"|
*4" or 6"
|-
| style="background:LightGrey; color:black"|Substrate material allowed
|style="background:WhiteSmoke; color:black"|
*Silicon wafers
*
|-
| style="background:LightGrey; color:black"|Material allowed on the substrate
|style="background:WhiteSmoke; color:black"|
*
|-
|}
==Film quality optimization==
==Film quality optimization==
''By Bjarke Thomas Dalslet @Nanotech.dtu.dk''
''By Bjarke Thomas Dalslet @Nanotech.dtu.dk''

Revision as of 11:40, 28 October 2010

LESKER Sputter Tool

The purpose of the sputter is to deposit magnetic metals and dielectrica on a single 4" or 6" wafer at a time.

It can be a problem to take wafers from the sputter and into the other machines in the cleanroom, since it is not very clean. In principle the sputter should be the last step before you take your wafers out of the cleanroom. If you need to take process your wafers further please contact the PVD group so they can help you.

Lift off should never be done in the normal lift off bath in RR4 it should always be done in the dedicated lift off bath opposite the sputter.


Materials for sputtering

Contcat the pvd-group if you have special needs (pvd@danchip.dtu.dk).


Overview of the performance of Alcatel and some process related parameters

Purpose Deposition of magnetic metals and dielectrica
  • Sputtering of magnetic metals and Silicon
Performance Film thickness
Deposition rates
Process parameter range Process Temperature
  • 100-200C
Process pressure
  • 3-5 mTorr
Process Gases
  • Ar
  • N
  • O
Substrates Batch size
  • 4" or 6"
Substrate material allowed
  • Silicon wafers
Material allowed on the substrate


Film quality optimization

By Bjarke Thomas Dalslet @Nanotech.dtu.dk

The Lesker CMS 18 sputter system can produce films in a wide range of qualities. The quality of a film depends strongly on the substrate (lattice matching), but also on the energy the sputtered material can utilize for annealing.

Strain estimations was done on 30 nm NiFe thin films using low angle x-ray diffraction, for various substrates. It was found that the strain of the film influenced the resistance (R) and anisotropic magneto resistance (AMR) of the films (this relationship is also documented in literature); A Ta interface layer reduced R and increased AMR on both Si and SiO substrates while reducing strain.

This study was then done on 30 nm NiFe thin films deposited on 3 nm Ta on top of a SiO substrate, using R and AMR as an indication of strain. As seen in the tables, applying a substrate bias increases AMR and conductance (1/R). An equivalent effect is seen when heating the substrate during deposition. This heating can also be done after deposition without loosing the effect.

Name Substrate bias (W) AMR 1/R (S) Crystal strain
0029 NiFe3_stack_RF20 20 0.02724278 1.308044474
0018_NiFe1_stack_RF 10 0.025850358 0.898311175
0030 NiFe3_stack 0 0.020103598 0.71772052 0.8


Name Temperature (C) AMR 1/R (S) Crystal strain
0030 NiFe3_stack 25 0.020103598 0.71772052 0.8
BDT-NiFe1-blank30 200 0.019319002 1.095770327
BTD-NiFe-Blank22 250 0.021768497 1.047668937
BTD-NiFe-Blank14 300 0.02983617 1.724137931
BTD-NiFe-Blank13 350 0.033944331 1.887504719
BTD-NiFe-Blank15 400 0.031176801 1.655903295 0.2
BTD-NiFe-Blank16 450 0.030843457


Surface roughness optimization

By Bjarke Thomas Dalslet @Nanotech.dtu.dk

The Lesker CMS 18 sputter system provides thin films of varying surface roughness. This roughness was verified to be dependent on the sputtered material, sputter mode (DC or RF) and the substrate bias strength. Other probable factors include sputter power and pressure. Below is a table for three cases.

The "From SiO target (RF sputter)" study was done on clean Si substrates. The sputter power was 157W and the pressure 3.5 mTorr using RF sputtering of a SiO target. The film thicknesses were around 42 nm.

The "From Si target (DC sputter)" study was done on clean Si substrates. The sputter pressure 3 mTorr using DC reactive sputtering of a Si target. Oxygen was added to the argon sputter gas. Above 10% O the gun seems to oxidize (at this sputter power). Figure 1 shows the difference in AFM images between no RF bias (wafer 12) and RF bias (Wafer 21).

The "Ta" study was done on clean Si substrates. The sputter pressure was 3 mTorr using DC sputtering of a Ta target. Some O was added to wafer 25 and 26 to make TaO. In order to get fully oxidized films, up to 30-45% O should be added. Consult the thesis of Carsten Christensen for details on TaO.

Other studies on metals (NiFe/MnIr) show only limited effect of the substrate bias on the roughness.


From SiO2 target (RF sputter)

Wafer nr RF bias (W) Reactive O2 (%) Power(W) Rq (RMS) (nm) Thickness
3 0 0 157 0.902
6 5 0 157 0.499 44
7 10 0 157 0.142 42
8 15 0 157 0.422 40


From Si target (DC sputter)

Wafer nr RF bias (W) Reactive O2 (%) Power(W) Rq (RMS) (nm) Thickness
12 0 5 135 1.44 123 nm (ellipsometry)
13 0 9 130 1.32 98 nm (ellipsometry)
14 0 13 100 1.37 71.5 nm (ellipsometry)
15 10 9 90 0.984 56.25 nm (ellipsometry)
21 20 9 90 0.112
22 15 9 90 0.509


Ta

Wafer nr RF bias (W) Reactive O2 (%) Power(W) Rq (RMS) (nm) Thickness
blank1 0 0 180 0.209
16 10 0 180 0.36 56
24 20 0 180 0.357
25 20 9 180 0.202 110
26 20 5 180 0.194 95
27 15 0 180 0.413
28 25 0 180 0.164
31 30 0 180 0.3


Figure 1:Left: no RF bias (wafer 12) gives high roughness. Right: RF bias (Wafer 21) gives low roughness


Oxide insulation analysis

by Bjarke Thomas Dalslet @Nanotech.dtu.dk

The wafers in this analysis consisted of a Si substrate with no native oxide. A layer of SiO was reactively sputtered (9% O2 90 W 3.5 mTorr). After that, using a shadow mask, 200nm thick gold rectangles was electro deposited on top of the oxide. Gold was also electro deposited on the back side. Then the impedance as a function of frequency was recorded.

The figure shows the measurements for different oxide thicknesses. Most of the measurements show perfect capacitors, although for illustration measurements with a few pinholes and with many pinholes is also shown for the 20 nm sample.

The success rate for the different thicknesses can be seen in the table, together with the number of samples measured and the number of perfect capacitors.

It is possible to make perfect capacitors with oxide thicknesses down to and including 5 nm and possibly even thinner, although the failure rate increases. Bear in mind, though that each structure measured here has an area of 8 mm2 - for a 1 mm2 structure the failure rate would be much lower, assuming the short circuits are not located on the sides of the structures.


alt text


Name Thickness [nm] # samples measured # good capacitors Success rate [%]
38 5 11 1 9
39 10 10 2 20
40 20 7 3 43
41 30 7 7 100
37 50 7 7 100