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ALD 2 (PEALD)

Thermal ALD and PEALD

The ALD 2 (PEALD) is used to deposit very thin and uniform layers of different materials, by use of thermal ALD (Atomic Layer Deposition) or PEALD (Plasma Enhanced ALD). Layers can be up to 100 nm thick, see the table below.

The ALD deposition takes place in an ALD reactor chamber. In order to ensure that the temperature inside this reactor is the same everywhere, it has a dual chamber structure. The inner chamber is the reactor chamber, and the outer chamber is isolating the reactor chamber from room air. Both the inner and the outer chamber are under vacuum. The space between the two chambers is called an intermediate space (IMS), and the IMS is constantly purged with nitrogen.

When a sample is loaded into the reactor chamber, it will take some time before it reaches the desired temperature. Thus, it is important to include a temperature stabilization time in the deposition recipes.

The ALD depositions take place under vacuum, thus a vacuum pump is connected to the bottom of the ALD reactor chamber. The pump is located in the basement.

Different precursor lines are connected to the reactor chamber through separate precursor inlets. At the moment the available precursors here are TMA, TiCl₄, SAM24, TEMAHf, H₂O and NH₃, and soon O₃ will also be available. These precursor lines are all purged with a constant flow of nitrogen.

The liquid precursor sources TMA, TiCl₄ and H₂O are stored in bottles located in a side cabinet on the left side of the machine. When the TMA and TiCl₄ precursors are not in use, a manual valve on each bottle has to be closed. The powder precursors SAM24 and TEMAHf are stored in bottles located in a big cabinet below the ALD chamber. These precursors are heated by heating jackets, and users should not open and close the manual valves. O₃ is generated by use of an ozone generator that is located in the E-rack at the right side of the machine.

A remote plasma generator is connected to the upper part of the reactor chamber. Different precursor gases are connected to this plasma generator through the same gas inlet. At the moment the available plasma precursor gases are N₂, O₂, NH₃ and H₂. The plasma gas inlet is constantly purged with argon. The plasma gases can also be used as precursors for thermal ALD if the power to the plasma generator is not turned on. When H₂ is being used, the pump line constantly has to be purged with 1.9 SLM nitrogen, and this has to be enabled manually.

The plasma generator is separated from the reactor chamber by a plasma cone (or chamber lid). The argon flow through the plasma gas inlet ensures that the plasma cone remains clean.

The plasma cone is not heated, and thus is will affect the temperature uniformity in the reactor chamber, and it will affect the gas flows and increase the necessary purge time. For that reason it is possible to mount a thermal lid between the plasma cone and the reactor chamber. However, it is quite time consuming to install the thermal lid as it requires that the machine is cooled to room temperature and vented. Furthermore, it is not possible to run plasma processes with the thermal lid installed.

The precursor pulse time is controlled by special ALD valves that allow very short precursor pulses to be introduced into the ALD reactor chamber and at the same time allow a constant nitrogen or argon flow. Thus, nitrogen and argon are always flowing through the ALD valves into the chamber, independent on whether a precursor pulse is introduced or not.

At the moment it is possible to deposit Al₂O₃, TiO₂, HfO₂, SiO₂, AlN and TiN in the ALD. In order to deposit good quality nitride layers with low sheet resistance, the amount of oxygen has to be very low. Thus, the ALD reactor chamber has to be passivated for about three days, before nitride depositions can be done, and oxides and nitrides cannot be deposited at same time.

Samples are loaded through a load lock. 6" and 8" wafers can be loaded directly in the load lock, while 4" wafers and smaller samples have to be placed on a 6" carrier plate or a 6" silicon dummy wafer with an etched recess. It is only possible to load one wafer or carrier plate at a time by use of the load lock.

The plasma cone is opened and closed, when samples are transferred between the load lock and the reactor chamber. Two buttons on the load lock are used to insert and retract the load lock arm from the reactor chamber. A window on the front side of the machine makes it possible to keep an eye on the reactor chamber and the sample during loading and unloading.

It is also possible to load a minibatch directly holder into ALD through a door on the left side of the reactor chamber. However, a training is needed in order to use the minibatch holder, and for nitride depositions the minibatch holder cannot be used as it requires that the machine is vented, and thus a possible nitride passivation will be ruined. Furthermore, the minibatch holder is not useful for plasma process, as the ALD material will only be deposited on the top sample.

The ALD is controlled by use of a computer with a touch screen that is situated next to the machine.

The ALD 2 (PEALD) is a Picosun R-200 Advanced Plasma ALD manufactured by Picosun, and it was installed in the cleanroom in 2016.

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

ALD 2 (PEALD) info page in LabManager

Process information

Standard recipes on ALD 2 (PEALD):

Standard recipes on the ALD 2 (PEALD)

Available processes:

Al₂O₃ deposition using ALD 2 (PEALD)

TiO₂ deposition using ALD 2 (PEALD)

HfO₂ deposition using ALD 2 (PEALD)

SiO₂ deposition using ALD 2 (PEALD) - The process is obsolete

AlN deposition using ALD 2 (PEALD)

TiN deposition using ALD 2 (PEALD)

Al₂O₃ deposition using ALD 2 (PEALD) at room temperature

Equipment performance and process related parameters

Equipment		ALD 2 (PEALD)
Purpose	Thermal ALD or PEALD deposition	Al₂O₃ - Thermal Al₂O₃ (mainly backup for ALD1) and Al₂O₃ using plasma TiO₂ (amorphous or anatase) - Thermal TiO₂ (mainly backup for ALD1) and TiO₂ using plasma HfO₂ - Thermal HfO₂ (mainly backup for ALD1) AlN - AlN using plasma TiN - Thermal TiN and TiN using plamsa ZnO AZO All precursors might not be available at the same time. Is is not possible to deposit oxides and nitrides at the same time.
Performance	Deposition rates	Depending on the deposited materials and temperature. More information can be found on the pages under "Process information"
Performance	Thickness	Oxides: Al₂O₃, TiO₂, HfO₂, ZnO, AZO: 0-100 nm Nitrides: SiO₂, AlN, TiN: 0-100 nm As the purpose of ALD 2 is to deposit very thin and uniform layers, the allowed deposition thickness is limited to 100 nm, and it is not allowed to do more depositions on the same sample(s) to deposit thicker layers than 100 nm. Deposition of thicker layers is not allowed, because this will occupy the machine for long time and thus make it available for less users. Long depositions also cause issues and with flakes and particles, which means that the chamber and the pump line will have to be cleaned or changed quite often. Furthermore, the delivery time on precursors is usually quite long. So when you make a sample design, you should avoid steps, where you need to deposit thicker layers than 100 nm with ALD, or you can consider, if the same material can be deposited using other machines in the cleanroom.
Process parameter	Deposition temperature	Maximum 500 ^oC
	Thermal precursors	TMA - Trimethylaluminium TiCl₄ - Titaniumtetrachloride H₂O - Water O₃ - Ozone. Not available at the moment NH₃ - Ammonia SAM24 - Bis(diethylamono)silane TEMAHf - Tetrakis(ethylmethylamino)hafnium
	Plasma precursors	N₂ O₂ NH₃ H₂
Substrates	Batch size	Smaller samples - Loaded on a 150 mm carrier plate or dummy wafer with an etched recess through the load lock One 100 mm wafer - Loaded on a 150 mm carrier plate or dummy wafer with an etched recess through the load lock One 150 mm wafer - Loaded directly through the loadlock One 200 mm wafer - Loaded directly through the loadlock For thermal ALD depositions of oxides, there is room for up to five wafers. 100, 150 and 200 mm wafers have to be loaded directly into the ALD chamber
	Allowed materials	Silicon Silicon oxide, silicon nitride Quartz/fused silica Metals - Use a dedicated carrier wafer III-V materials - Use a dedicated carrier wafer Polymers - Depending on the melting point/deposition temperature, use carrier wafer. Ask for permission

@@ Line 1: / Line 1: @@
-=ALD Picosun 200=
+'''Feedback to this page''': '''[mailto:labadviser@danchip.dtu.dk?Subject=Feed%20back%20from%20page%20http://labadviser.danchip.dtu.dk/index.php/Specific_Process_Knowledge/Thin_film_deposition/ALD2_(PEALD) click here]'''
-=<span style="background:#FF2800">THIS PAGE IS UNDER CONSTRUCTION</span>[[image:Under_construction.png|200px]]=
-'''Feedback to this page''': '''[mailto:labadviser@danchip.dtu.dk?Subject=Feed%20back%20from%20page%20http://labadviser.danchip.dtu.dk/index.php/ALD_Picosun_R200 click here]'''
+''This page is written by DTU Nanolab internal''
+=ALD 2 (PEALD)=
 [[Category: Equipment|Thin film]]
 [[Category: Thin Film Deposition|ALD]]
-== ALD - Atomic layer deposition ==
-[[image:ALD2.jpg|300x300px|right|thumb|Picosun R200 PEALD, positioned in cleanroom F-2.]]
-The ALD2 is a PEALD (Plasma Enhances Atomic Layer Deposition) tool. The machine is used to deposit very thin layers of different materials, one atomic layer at a time, by use of thermal ALD or plasma assisted ALD.
+== Thermal ALD and PEALD ==
+[[image:ALD2.jpg|450x450px|right|thumb|ALD 2 (PEALD). Positioned in cleanroom F-2.]]
-The ALD deposition takes place in a ALD reactor. In order to ensure that the ALD reactor has the same temperature everywhere, it has a dual chamber structure. The inner chamber is the reactor chamber, and the outer chamber is isolating the reactor chamber from room air. Both the inner and outher chamber are under vacuum. The space between the two chambers is called an intermediate space (IMS), and the IMS is constantly purged with nitrogen.
+The ALD 2 (PEALD) is used to deposit very thin and uniform layers of different materials, by use of thermal ALD (Atomic Layer Deposition) or PEALD (Plasma Enhanced ALD). Layers can be up to 100 nm thick, see the table below.
-When a sample is loaded into the reactor chamber, it will take some time before it reaches the desired temperature. Thus, it is important to include a temperature stabilization time in the deposition recipes.
+The ALD deposition takes place in an ALD reactor chamber. In order to ensure that the temperature inside this reactor is the same everywhere, it has a dual chamber structure. The inner chamber is the reactor chamber, and the outer chamber is isolating the reactor chamber from room air. Both the inner and the outer chamber are under vacuum. The space between the two chambers is called an intermediate space (IMS), and the IMS is constantly purged with nitrogen.
-The ALD depositions take place under vacuum, thus a vacuum pump is connected to the bottom of the ALD reactor. The pump is located in the basement.
+When a sample is loaded into the reactor chamber, it will take some time before it reaches the desired temperature. Thus, it is important to include a temperature stabilization time in the deposition recipes.
-Different precursors are connected to the reactor chamber through separate gas lines. At the moment the available precursors are TMA, TiCl<sub>4</sub>, SAM24, TEMAHf, H<sub>2</sub>0 and NH<sub>3</sub>, and soon O<sub>3</sub> will also be available. These gas lines are all purged with a constant flow of nitrogen.
+The ALD depositions take place under vacuum, thus a vacuum pump is connected to the bottom of the ALD reactor chamber. The pump is located in the basement.
-The precursor sources TMA, TiCl<sub>4</sub> and H<sub>2</sub>0 are located in a side cabinet on the left side of the machine. When these precursors are not in use, the manual valves have to be closed. The precursors SAM24 and TEMAHf are located in the big cabinet below the ALD chamber. These precursors are heated by a heating jacked, and users should not close the manual valves. O<sub>2</sub> is generated by use of an ozone generator that is located in the E-rack at the right side of the machine.
+Different precursor lines are connected to the reactor chamber through separate precursor inlets. At the moment the available precursors here are TMA, TiCl<sub>4</sub>, SAM24, TEMAHf, H<sub>2</sub>O and NH<sub>3</sub>, and soon O<sub>3</sub> will also be available. These precursor lines are all purged with a constant flow of nitrogen.
-A remote plasma generator is connected to the upper part of the reactor chamber. Different precursor gasses are connected to this plasma generator through the same gas inlet. At the moment the available plasma precursor gasses are N<sub>2</sub>, O<sub>2</sub> and NH<sub>3</sub>. The plasma gas inlet is constantly purged with argon. The plasma gasses can also be used as normal precursors if the power to the plasma generator is not turned on.
+The liquid precursor sources TMA, TiCl<sub>4</sub> and H<sub>2</sub>O are stored in bottles located in a side cabinet on the left side of the machine. When the TMA and TiCl<sub>4</sub> precursors are not in use, a manual valve on each bottle has to be closed. The powder precursors SAM24 and TEMAHf are stored in bottles located in a big cabinet below the ALD chamber. These precursors are heated by heating jackets, and users should not open and close the manual valves. O<sub>3</sub> is generated by use of an ozone generator that is located in the E-rack at the right side of the machine.
-The plasma generator is separated from the reactor chamber by a plasma cone. The argon flow through the plasma gas inlet will ensure that the plasma cone remains clean.
+A remote plasma generator is connected to the upper part of the reactor chamber. Different precursor gases are connected to this plasma generator through the same gas inlet. At the moment the available plasma precursor gases are N<sub>2</sub>, O<sub>2</sub>, NH<sub>3</sub> and H<sub>2</sub>. The plasma gas inlet is constantly purged with argon. The plasma gases can also be used as precursors for thermal ALD if the power to the plasma generator is not turned on. When H<sub>2</sub> is being used, the pump line constantly has to be purged with 1.9 SLM nitrogen, and this has to be enabled manually.
-The precursor pulse time is controlled by special ALD valves that allow very short precursor pulses to be introduced into the reactor chamber and at the same time allow a constant nitrogen or argon flow. Thus, nitrogen and argon is always flowing through the ALD valves into the chamber, independent on whether a precursors pulse is introduced or not.
+The plasma generator is separated from the reactor chamber by a plasma cone (or chamber lid). The argon flow through the plasma gas inlet ensures that the plasma cone remains clean.
-The plasma cone is not heated, and thus is will affect to temperature uniformity in the reactor chamber, and it will affect the gas flow and increase the necessary purge time. For that reason it is possible to mount a thermal lid between the plasma cone and the reactor chamber. However, it is quite time consuming to install the thermal lid as this requires that the machine is cooled to room temperature and vented. Furthermore, it is not possible to run a plasma process with the thermal lid installed.
+The plasma cone is not heated, and thus is will affect the temperature uniformity in the reactor chamber, and it will affect the gas flows and increase the necessary purge time. For that reason it is possible to mount a thermal lid between the plasma cone and the reactor chamber. However, it is quite time consuming to install the thermal lid as it requires that the machine is cooled to room temperature and vented. Furthermore, it is not possible to run plasma processes with the thermal lid installed.
-If only the precursors connected to the gas inlets at the reactor chamber are used for a deposition, this is called a thermal ALD reaction. If the plasma generator is used to make one of the precursors, the deposition is called a plasma assisted ALD (PEALD) reaction.
+The precursor pulse time is controlled by special ALD valves that allow very short precursor pulses to be introduced into the ALD reactor chamber and at the same time allow a constant nitrogen or argon flow. Thus, nitrogen and argon are always flowing through the ALD valves into the chamber, independent on whether a precursor pulse is introduced or not.
-At the moment it is possible to deposit Al<sub>2</sub>O<sub>3</sub>, TiO<sub>2</sub>, HfO<sub>2</sub>, SiO<sub>2</sub>, AlN and TiN in the ALD. In order to deposit a good nitride layer with a low sheet resistance, the amount of oxygen has to be very low. Thus, the chamber has to be passivated before nitride depositions can be done, and oxides and nitrides cannot be deposited at same time.
+At the moment it is possible to deposit Al<sub>2</sub>O<sub>3</sub>, TiO<sub>2</sub>, HfO<sub>2</sub>, SiO<sub>2</sub>, AlN and TiN in the ALD. In order to deposit good quality nitride layers with low sheet resistance, the amount of oxygen has to be very low. Thus, the ALD reactor chamber has to be passivated for about three days, before nitride depositions can be done, and oxides and nitrides cannot be deposited at same time.
-Thermal ALD depositions are normally fastest and easiest to control, but the reactions can only take place at an elevated temperature. By PEALD plasma can be used instead of a high temperature in order to deliver the necessary activation energy for the ALD reaction to take place, and it is possible to deposit more different materials.
+Samples are loaded through a load lock. 6" and 8" wafers can be loaded directly in the load lock, while 4" wafers and smaller samples have to be placed on a 6" carrier plate or a 6" silicon dummy wafer with an etched recess. It is only possible to load one wafer or carrier plate at a time by use of the load lock.
-Samples are loaded through a load lock. 6" and 8" wafers can be loaded directly in the load lock, while 4" wafers and smaller samples have to be placed on a 6" carrier plate or a 6" Si dummy wafer with an etched recess. It is only possible to load one wafer or carrier plate at a time.
+The plasma cone is opened and closed, when samples are transferred between the load lock and the reactor chamber. Two buttons on the load lock are used to insert and retract the load lock arm from the reactor chamber. A window on the front side of the machine makes it possible to keep an eye on the reactor chamber and the sample during loading and unloading.
-It is also possible to load a mini-batch holder into ALD through a door on the left side of the machine. However, this option is normally not available as it requires that the machine is vented, and thus a possible nitride passivation will be ruined. Furthermore, for plasma processes it is only possible to deposit on one wafer or sample holder at a time.
+It is also possible to load a minibatch directly holder into ALD through a door on the left side of the reactor chamber. However, a training is needed in order to use the minibatch holder, and for nitride depositions the minibatch holder cannot be used as it requires that the machine is vented, and thus a possible nitride passivation will be ruined. Furthermore, the minibatch holder is not useful for plasma process, as the ALD material will only be deposited on the top sample.
 The ALD is controlled by use of a computer with a touch screen that is situated next to the machine.
-A short presentation with some information about the ALD tool can be found [[Media:ProcessMeeting ALD 2013-12-06_1.pdf|here]].
+The ALD 2 (PEALD) is a Picosun R-200 Advanced Plasma ALD manufactured by Picosun, and it was installed in the cleanroom in 2016.
 '''The user manual, the user APV and contact information can be found in LabManager:'''
-!![http://labmanager.danchip.dtu.dk/function.php?module=Machine&view=view&mach=321 ALD Picosun R200 info page in LabManager],!! ALD1 skal ændres når ALD2 siden bliver klar
+[http://labmanager.dtu.dk/function.php?module=Machine&view=view&mach=365 ALD 2 (PEALD) info page in LabManager]
 == Process information ==
-*[[/Standard recipes on the ALD2 tool|Standard recipes on the ALD2 tool]]
+'''Standard recipes on ALD 2 (PEALD):'''
-*[http://labadviser.danchip.dtu.dk/index.php/Specific_Process_Knowledge/Thin_film_deposition/ALD_Picosun_R200/ALD_multilayers Advanced recipes involving fabrication of multilayers done on '''ALD1''']]
-*[http://labadviser.danchip.dtu.dk/index.php/Specific_Process_Knowledge/Thin_film_deposition/ALD_Picosun_R200/Al2O3_deposition_using_ALD Al<sub>2</sub>O<sub>3</sub> deposition using '''ALD1''']
+*[[/Standard recipes on the ALD2 tool|Standard recipes on the <b>ALD 2 (PEALD)</b>]]
-*[http://labadviser.danchip.dtu.dk/index.php/Specific_Process_Knowledge/Thin_film_deposition/ALD_Picosun_R200/TiO2_deposition_using_ALD TiO<sub>2</sub> deposition using '''ALD1''']
+'''Available processes:'''
+*[[/Al2O3 deposition using ALD2| Al<sub>2</sub>O<sub>3</sub> deposition using '''ALD 2 (PEALD)''']]
+*[[/TiO2 deposition using ALD2| TiO<sub>2</sub> deposition using '''ALD 2 (PEALD)''']]
+*[[/HfO2 deposition using ALD2| HfO<sub>2</sub> deposition using '''ALD 2 (PEALD)''']]
+*[[/SiO2 deposition using ALD2| SiO<sub>2</sub> deposition using '''ALD 2 (PEALD)''' - The process is obsolete]]
+*[[/AlN deposition using ALD2| AlN deposition using '''ALD 2 (PEALD)''']]
+*[[/TiN deposition using ALD2| TiN deposition using '''ALD 2 (PEALD)''']]
+*[[/Al2O3 deposition using plasma ALD2 at room temperature| Al<sub>2</sub>O<sub>3</sub> deposition using '''ALD 2 (PEALD)''' at room temperature]]
 ==Equipment performance and process related parameters==
@@ Line 60: / Line 77: @@
 !colspan="2" border="none" style="background:silver; color:black;" align="center"|Equipment
-|style="background:WhiteSmoke; color:black"|<b>ALD2 (PEALD)</b>
+|style="background:WhiteSmoke; color:black"|<b>ALD 2 (PEALD)</b>
 |-
 !style="background:silver; color:black;" align="center" width="60"|Purpose
-|style="background:LightGrey; color:black"|ALD (atomic layer deposition) of
+|style="background:LightGrey; color:black"|Thermal ALD or PEALD deposition
 |style="background:WhiteSmoke; color:black"|
-*Al<sub>2</sub>O<sub>3</sub>
+*Al<sub>2</sub>O<sub>3</sub> - Thermal Al<sub>2</sub>O<sub>3</sub> (mainly backup for ALD1) and Al<sub>2</sub>O<sub>3</sub> using plasma
-*TiO<sub>2</sub> (amorphous or anatase)
+*TiO<sub>2</sub> (amorphous or anatase) - Thermal TiO<sub>2</sub> (mainly backup for ALD1) and TiO<sub>2</sub> using plasma
-*SiO<sub>2</sub>
+*HfO<sub>2</sub> - Thermal HfO<sub>2</sub> (mainly backup for ALD1)
-*HfO<sub>2</sub>
+*AlN - AlN using plasma
-*TiN
+*TiN - Thermal TiN and TiN using plamsa
-*AlN
+*ZnO
+*AZO
+All precursors might not be available at the same time.
+Is is not possible to deposit oxides and nitrides at the same time.
 |-
 !style="background:silver; color:black" align="center" valign="center" rowspan="2"|Performance
 |style="background:LightGrey; color:black"|Deposition rates
 |style="background:WhiteSmoke; color:black"|
-*Al<sub>2</sub>O<sub>3</sub>: ~ 0.075 - 0.097 nm/cycle (Using the "Al2O3" recipe, depending on the temperature). Result from ALD1
+Depending on the deposited materials and temperature.
-*TiO<sub>2</sub>: 0.041 - 0.061 nm/cycle (Using the "TiO2" recipe, depending on the temperature). Result from ALD1
+More information can be found on the pages under "Process information"
 |-
 |style="background:LightGrey; color:black"|Thickness
 |style="background:WhiteSmoke; color:black"|
-*Al<sub>2</sub>O<sub>3</sub>: 0 - 100 nm
+*Oxides: Al<sub>2</sub>O<sub>3</sub>, TiO<sub>2</sub>, HfO<sub>2</sub>, ZnO, AZO: 0-100 nm
+*Nitrides: SiO<sub>2</sub>, AlN, TiN: 0-100 nm
+<i>As the purpose of ALD 2 is to deposit very thin and uniform layers, the allowed deposition thickness is limited to 100 nm, and it is not allowed to do more depositions on the same sample(s) to deposit thicker layers than 100 nm. Deposition of thicker layers is not allowed, because this will occupy the machine for long time and thus make it available for less users. Long depositions also cause issues and with flakes and particles, which means that the chamber and the pump line will have to be cleaned or changed quite often. Furthermore, the delivery time on precursors is usually quite long. So when you make a sample design, you should avoid steps, where you need to deposit thicker layers than 100 nm with ALD, or you can consider, if the same material can be deposited using other machines in the cleanroom.</i>
 |-
 !style="background:silver; color:black" align="center" valign="center" rowspan="3"|Process parameter
-|style="background:LightGrey; color:black"|Temperature
+|style="background:LightGrey; color:black"|Deposition temperature
 |style="background:WhiteSmoke; color:black"|
-*Al<sub>2</sub>O<sub>3</sub>: 150 - 350 <sup>o</sup>C
+Maximum 500 <sup>o</sup>C
 |-
-|style="background:LightGrey; color:black"|Precursors
+|style="background:LightGrey; color:black"|Thermal precursors
 |style="background:WhiteSmoke; color:black"|
 *TMA - Trimethylaluminium
 *TiCl<sub>4</sub> - Titaniumtetrachloride
 *H<sub>2</sub>O - Water
-*O<sub>3</sub> - Ozone
+*O<sub>3</sub> - Ozone. Not available at the moment
 *NH<sub>3</sub> - Ammonia
 *SAM24 - Bis(diethylamono)silane
@@ Line 102: / Line 124: @@
 *O<sub>2</sub>
 *NH<sub>3</sub>
-*(4% H<sub>2</sub> in N<sub>2</sub>) will be installed later
+*H<sub>2</sub>
 |-
 !style="background:silver; color:black" align="center" valign="center" rowspan="3"|Substrates
 |style="background:LightGrey; color:black"|Batch size
 |style="background:WhiteSmoke; color:black"|
-*Samll samples and single wafers are loaded through the load lock
+*Smaller samples - Loaded on a 150 mm carrier plate or dummy wafer with an etched recess through the load lock
-*100 mm and smaller are loaded on a carrier plate (150 mm)
+*One 100 mm wafer - Loaded on a 150 mm carrier plate or dummy wafer with an etched recess through the load lock
-*150 mm or 200 mm wafer don't need the carrier plate
+*One 150 mm wafer - Loaded directly through the loadlock
-*Up to 5 wafers when doing thermal ALD of oxides wafer size 100 mm, 150 mm and 200 mm
+*One 200 mm wafer - Loaded directly through the loadlock
+*For thermal ALD depositions of oxides, there is room for up to five wafers. 100, 150 and 200 mm wafers have to be loaded directly into the ALD chamber
 |-
 | style="background:LightGrey; color:black"|Allowed materials
@@ Line 117: / Line 140: @@
 *Silicon oxide, silicon nitride
 *Quartz/fused silica
-*Al, Al<sub>2</sub>O<sub>3</sub>
+*Metals - Use a dedicated carrier wafer
-*Ti, TiO<sub>2</sub>
+*III-V materials - Use a dedicated carrier wafer
-*Other metals (use dedicated carrier wafer)
+*Polymers - Depending on the melting point/deposition temperature, use carrier wafer. Ask for permission
-*III-V materials (use dedicated carrier wafer)
-*Polymers (depending on the melting point/deposition temperature, use carrier wafer)
 |-
 |}