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The cluster-based multi-chamber high-vacuum sputtering deposition system is a robotic cluster tool with two deposition chambers sharing the same distribution transfer station and load-lock. The equipment was installed and accepted in the clean room in January 2020. The purpose of the tool is to deposit a variety of materials using DC/RF/Pulse DC/HIPIMS magnetron sputtering, with or without RF substrate bias.

In PC 1 (process chamber 1), it is possible to deposit any material using 6 x 3” magnetron sources with N₂ or O₂ reactive gases.

PC 3 (process chamber 3) is dedicated to oxygen-free materials - nitrides and metals. It is equipped with 1 x 4” + 2 x 3” magnetrons and supplied with N₂ process gas for reactive deposition. Both chambers allow heating of substrates up to 600 ^oC. The equipment is located in Cleanroom A-5, where users can access the cassette loader.

Manufacture: Kurt J. Lesker Company

Model: 2017 PRO Line PVD75 thin film deposition cluster system

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

Sputter-System Metal-Oxide(PC1)

Sputter-System Metal-Nitride(PC3)

The Thin Film group thinfilm@nanolab.dtu.dk is responsible for the equipment.

Target/Metal requests should be sent to metal@nanolab.dtu.dk.

If you need training on the machine, please send your request to: training@nanolab.dtu.dk.

Sputtering deposition system set-up

The cluster sputter system is used for depositing metals, magnetic metals, and dielectrics on a single 4" or 6" wafer or multiple small samples. Samples will be placed on the ten-shelf cassette and loaded in the load lock module. After the load lock chamber is pumped down, the sample can be transferred to the desired process chamber. The sample will be rotated over the target and can be heated to up to 600 °C while the film is being deposited. The system is equipped with two process chambers connected to a wafer transfer robot and a load lock chamber.

• System set-up and power supply configuration.
• 
  The system set-up showing the different operation chambers and power supplies network.
  *HSM - High Strengh Magnet.
  **RGA - Residual Gas Analyser.

Power supply configuration

Power supply specifications are presented in a table below.

Sputter-System Metal-Oxide (PC1)

Chamber PC1 consists of six KJLC Torus® 3" magnetron sputtering sources with the possibility of RF, DC, Pulse DC, and HIPIMS sputtering. There are Argon, Nitrogen, and Oxygen gas lines connected to this chamber. It is possible to apply an RF bias to the substrate, which can be used for substrate cleaning before deposition or during deposition to alter the film properties. Deposition of magnetic materials requires a high-strength magnet (HSM), which must be installed on source 3 in PC1. The chamber allows co-sputtering (sputtering from two or more sources simultaneously) as long as the sources are not connected to the same power supply.

• Process chamber (PC 1)
• 
  Photo of the chamber.
• 
  Deposition from source 2.

Sputter-System Metal-Nitride (PC3)

The second process chamber, designated as PC3, comprises two KJLC Torus 3" magnetron sputtering sources and one height-adjustable KJLC Torus 4" magnetron sputtering source, which also supports RF, DC, Pulse DC, and HiPIMS sputtering modes. It is possible to apply an RF bias to the substrate, which can be used to clean the substrate before deposition or during deposition to alter the film properties. The chamber allows co-sputtering (sputtering from two or more sources simultaneously) as long as the sources are not connected to the same power supply. A residual gas analyzer (RGA) mounted on the chamber allows monitoring post-process chemical gas traces. To operate the analyzer, the chamber must be pumped to its base pressure.

• Process chamber PC 3
• 
  Photo of the chamber.
• 
  Deposition from source 2.

Distribution Chamber (Genmark robot)

The load-lock and process chambers, PC1 and PC3, are connected through a standard distribution chamber. The robot arm can transfer the sample to the selected destination. During normal operation, the chamber is pumped to a base pressure, ensuring the safe transfer of the sample between chambers and the load lock without breaking the vacuum. The unit is connected to its turbo-pump.

• Distribution chamber (Robot). View from the service area.
• 
  The distribution chamber with and without the top cover.

Load-lock

The load lock chamber is the only part of the tool that users can access. Ventilation and pumping take approximately 5 minutes. The chamber has its turbo pump. Inside, there is a shelf with 10 cassette slots. The images below show the load lock set-up and sample mounting. The shelf is designed to handle 6-inch wafers, which have to be placed on dedicated carrier rings. The rings with wafers can be introduced onto the cassette shelf. Different adapters can be used for 4-inch wafers and small chips. After the load lock is pumped, it takes approximately. It takes 6 minutes to transfer the sample into the process chamber and 8 minutes to return.

• Cassette loader and sample mounling.
• 
  The load lock chamber.
• 
  Sample holder, carrier ring and load lock shelf.

Attention! The shelf turns to the opposite side from where the carrier ring is loaded. Furthermore, the shelf has to be placed properly inside the load lock. A carrier ring without a sample must never be loaded in the load lock. The light in the load lock chamber can be turned on. The light switch is located on the left side of the load-lock. Process chambers PC1 and PC3 are also equipped with light switches.

Process information

Excessive sputter power can cause damage to the target or sputter gun. Given the target/interface thermal limitations, such damage can be reduced/eliminated by using an appropriate maximum power. However, "appropriate" often equates to "low," and a low power setting means a low deposition rate. Once the appropriate power has been established for a given target/gun, never switch it on and immediately increase the power to that value. Always increase power slowly to its maximum value through a series of ramps. When the deposition run is complete, it is equally essential to ramp down power at the same rate as it was ramped up, allowing the target to cool slowly and avoid thermal shock and the potential for target fracture.

The table below shows the maximum power and maximum ramp-up/down power for available materials:

Additional information about the processes and equipment performace can be found here:

• Pre-acceptance test File:Cluster-based multi-chamber high vacuum sputtering deposition system pre acceptance.pptx

• Acceptance test File:Cluster Lesker P1 and P3 Acceptance test FOR LA PUBLICATION.pdf

Maximum Power Calculation

• ${\displaystyle PD}$ - Power density (fundamental constant given by a supplier)
• ${\displaystyle P(W)}$ - Power (W) from power supply
• ${\displaystyle A(inc{h}^2)}$ - Area of the target

${\displaystyle PD=\frac{P(W)}{A(inc{h}^2)}}$ ⇒ ${\displaystyle P(W)=PD\cdot A(inc{h}^2)=PD\cdot \frac{\pi d^2}{4}}$

• d=2" (2-inch target) ${\displaystyle P(W)=3.14\cdot PD}$

• d=3" (3-inch target) ${\displaystyle P(W)=7.065\cdot PD}$

• d=4" (4-inch target) ${\displaystyle P(W)=12.56\cdot PD}$

• d=6" (6-inch target) ${\displaystyle P(W)=28.26\cdot PD}$

Value of the ${\displaystyle PD}$ is material dependent and can be found on KJLC homepage

Standard recipe performance

There are 76 developed and tested process recipes for general users (48 for PC1 and 28 for PC3). They include non-reactive and reactive DC, RF, and PulseDC sputtering with or without substrate bias. Deposition using HiPIMS can only be performed with the assistance of DTU Nanolab staff. Starting the recipe, the user can adjust the relevant process parameters, including power, pressure, reactive gas ratio, rotation speed, substrate bias, and others. Each of the 76 recipes has a unique name which indicates the process chamber, type of sputtering (DC, RF, or Pulse DC), gas flow control, the type of reactive gas, and the presence of substrate bias. In addition to the standard process recipes, there are also recipes for substrate heating and RF cleaning.

• The build-up of the standard recipe name
• 
  The standard recipe has its unique name starting with the letters "MD", which stands for "Master Deposition".

So far, the following results can be used as a guide or reference: (Look for updated information in a specific material list).

Substrate heating

During the test by KJLC, using a wafer with thermocouples attached, the temperature of the wafer and the control thermocouple could be monitored. Generally, the sample temperature will be approximately 50 degrees lower than the temperature displayed on the system. There are software interlocks that control/protect the heater, as well as a hardware interlock that prevents the heater from turning on when the chamber is at atmospheric pressure or if there is insufficient water flow in the system.

There are software interlocks that prevent the transfer port from opening while the heater is on. Additionally, it will not allow the heater to turn on if there is no assigned wafer in the chamber, and it will not open the chamber vent valve if the temperature exceeds 80 °C.

There is no sensor to detect if a sample is physically present. If a user transfers an empty wafer carrier into a process chamber, the wafer ID will update accordingly, and the heater can be activated.

A sample transfer can be done while the sample is hot, but not while the heater is on. The heater thermocouples will cool very rapidly as soon as the heater is turned off, so there is no set temperature. A sample transfer unload should be done when the temperature is below 300 °C.

There are dedicated recipes to turn on a heater:

• If PC1 is used, select “Master Heater PC1 - On”

• If PC3 is used, select “Master Heater PC3 - On”

Substrate cleaning (RF Bias)

RF cleaning can be used to clean the sample before the deposition. There are dedicated recipes for that:

• If PC1 is used, select “Master Bias PC1_Upstream”

• If PC3 is used, select “Master Bias PC3_Upstream”

The user can select rotation speed (10 rpm), process pressure (1-15mTorr), RF power (maximum 100 W), and cleaning time (maximum 1800 s).

Batch process

The advanced system with the cassette loader and robot arm allow running a batch process ("Master Cassette" recipes). These processes are not among the standard recipes but can be developed by DTU Nanolab upon request.