Molecular beam epitaxyW is a method of thin film deposition that is useful for fabricating high performance photovoltaic devices.

MTU MBE background

Michigan Tech's MBE as discovered in 2011

The original MBE at Michigan Tech was assembled in 1993 using ISA Riber, SVT Associates, Thermionics, k-Space, and Inficon components. It provided staff and students the ability to deposit thin high purity films under ultra high vacuumW(UHV) conditions. The system saw use up until April of 2001, at which point it was left under UHV and powered down. In late 2011, over a decade later, the chamber was found to be at atmospheric pressure and the process of reconditioning the system was initiated.

Silver(Ag), molybdenum(Mo), germanium(Ge), tin(Sn), iron(Fe), nickel(Ni), copper(Cu), silicon(Si) and carbon(C) sources were used prior to 2001. The silicon and carbon sources were changed from thermal to SVT Associates electron beam evaporating sources roughly two years after completion of the MBE.

MBE Diagram similar to MTU's current model
Note: Diagram shown is a similar model to that of MTU's with the only known deviation from the diagram being the lack of the CF100 roof-top flange.

Installed Equipment

ISA RIBER MBE 32 Growth/Evaporation Chamber

The RIBER MBE 32 system is a highly flexible and efficient 3" single-wafer epi reactor, which provides all the necessary MBE tools and in-situ characterization capabilities to achieve state-of-the-art epitaxy of III-Vs, II-VIs, MCTs, nitrides and silicon alloys. The 8 cell ports are grouped together on the evaporation flange, which also includes cryoshrouds completely surrounding hot parts of the cells, ensuring maximum trapping of all residual species. The pump chamber also contains a cryoshroud to maximize gettering of low atomic weight gasses by the installed titanium sublimation pump system.

Two cryoshrouds are fixed to the inside of the source flange. One cryoshroud is a double-walled, lens-shaped assembly immediately adjacent the evaporation flange and serves to thermally isolate each of the sources while maximizing condensation of residual gasses. The second and main cryopshroud is supported by and connected to the evaporation flange. This cryoshroud has the same construction as the evaporation flange shroud. Each panel has a separate all metal liquid nitrogen inputs and outputs permitting independent or sequential cooling.

The evaporation flange can accommodate eight sources, four each with 2.75" and 4" flanges. It can be specifically adapted for the growth of mercury compounds or nitrides of group III elements. Gas-source MBE and CBE configurations combining the use of solid sources and/or gas sources are also available.

MTU Pneumatic Shutter Actuators

Michigan Tech's MBE system employs Model 16TTD manual shutters provided by ISA Riber and pneumatic rotary actuators(Bimba Pneu-Turn) are also available. The rotary actuators have been found, tested and deemed to be in working condition. A Humphrey Raceway solenoid valve consisting of nine (9) dual-use solenoids and a valve body capable of supplying nine actuators completes the automatic shutter system.

Introduction of samples is accomplished by use of a load lock chamber (R&D systems). This chamber can be vented (typically with UHP N2) and pumped independently of the evaporation chamber. In addition to the transfer arm sample holder, the chamber has attached to it two additional holders, one of which can be heated, for sample pre- and post-treatment. The sample transfer arm is manually operated, permitting limited rotation for alignment with the manipulator's sample holder.

MTU RIBER 3" Manipulator

The Ribar ARM3 manipulator provides rotation in two axes, one axis for placing the sample such that it faces towards or away from the sources and the other for rotation on an axis normal to the sample's face. It also permits heating of the sample to a maximum of 1000 degrees C. An Isa Riber MOB-300M molybdenum mounting block is specifically made for use with 3" diameter substrates but can accommodate mounting of smaller (2cm x 2cm) substrates with available carbon blanks.

Michigan Tech's ABN 135L Effusion Cells
RIBER ABN 135L Effusion Cell Diagram

A number of effusion cells are available for use; eight thermal and three e-gun cells. A plasma generator is also available. In situ analyzers consist of an Inficon Transpector residual gas analyzer, an Inficon SQC-310C deposition controller with two quartz crystal sensors and a reflection high energy electron diffraction (RHEED) system. One of the quartz crystal sensors is bellows-mounted and can be placed directly in the position occupied by the sample during film deposition, permitting very accurate deposition rate measurement.

Roughing is provided by a BOC Edwards QDP Drystar vacuum pump. Leybold Turbovac 1000C and Turbovac 361C turbomolecular pumps provide high vacuum pumping for the evaporation and load lock chambers, respectively. Ultra high vacuum conditions in the evaporation chamber are achieved with an ISA Riber PF-6 titanium sublimator and an ISA Riber PI-400-TTZ ion pump.


ISA RIBER PI-400-TTZ Ion Pump

ISA RIBER 401-1000 Ion Pump Power Supply

ISA RIBER PF-6 Titanium Sublimator

ISA RIBER Model 304-6 Titanium Sublimator Power Supply

Supplies power for Titanium filaments. 0 to 60 Amp selectable for 1 of 6 filaments and operates at 220V (50/60 Hz).


ISA RIBER Model JBA 12-1 Bayard-Alpert Ion Gauge

RIBER Model 307S2 Electrometer

ISA RIBER ABN 135L Effusion Cells

CELL TYPE SOLID SOURCE
MOUNTING FLANGE CONFLAT 2-3/4" O.D. CF 35
KNIFE EDGE TO LIP LENGTH 283.5 mm
EXTERNAL SHIELD DIAMETER 37.2 mm
BAKEOUT TEMPERATURE 250°C
CAPACITY 39 cc
CRUCIBLE INTERNAL LIP DIAMETER 23.6 mm
CRUCIBLE INTERNAL LENGTH 88.9 mm
CRUCIBLE MATERIAL PBN (pyrolytic boron nitride)
TEMPERATURE RANGE 0 - 1400°C
TEMPERATURE STABILITY < 0.4°C
THERMOCOUPLE TYPE WRe 5/26
HEATING MODE JOULE EFFECT / RADIATION
HEATING ASSEMBLY MATERIALS Mo - Ta - PBN
FILAMENT TYPE FLAT FOIL
MAXIMUM TEMPERATURE 1500°C
ISA RIBER TC 194 Temperature Control Units
MTU RIBER TC 194 Temperature Controllers











TDK-Lambda EMS 30-33 1000W (1kW) AC to DC Power Supply
MTU TDK EMS 30-33 Power Supplies
Michigan Tech currently has five(5) of these power supplies on hand, of which four are being utilized in the present
configuration for heating the manipulator and sources/cells. Current listed specifications are:


AC Input 1 kW models:

115 VAC (standard), 220 VAC (optional) single phase; All models 50/60 Hz

Rated Power (Watts) 1000W (1kW)
Output Voltage (Volts) 0 - 30V
Output Current (Amps) 0 - 33A
Output Ripple (mV) p-p Carrier 75mV
Output Characteristics Regulation: 0.1%

Stability: 0.05%

Transient response: 650 microseconds for 30% load change (models up to 20 VDC)

Operating temperature: 0-50 Deg C full output, derate above 50 Deg C

Protective Features Overvoltage (up to 300 VDC outputs)

Overtemperature

Overcurrent

Programming Front panel controls and remote analog resistance, voltage and current programming

SVT Associates EBS-4 Electron Beam Evaporator

SVTA-EBS Compact evaporator is a very versatile source for depositing thin layers of Carbon, Silicon, Tantalum, Molybdenum, and most other refractory metals that are manufactured in wire form. Its exclusive design utilizes an electron beam power supply for electron emission and an integral flux monitor to regulate the deposition rate. The source material is typically a rod of 1-5 mm in diameter. When held at a positive potential, it attracts electrons emitting from the filament and is heated to an evaporation temperature to produce a flux of atoms. A linear motion feed through provides adjustment of the source position. Alternatively, materials in chunk or powder form may be evaporated from a special crucible. Typical applications include silicon MBE- metallization, magnetic thin films, doping, interface studies etc.

SVTA 3kW Power Supply

RHEED Gun & CCD Camera

RHEED Image Analysis Hardware/Software package gives the user the necessary tools to gain insight into the thin film growth process and optimize material quality. The RHEED software is a multi-purpose program for analyzing RHEED patterns. The powerful software features tracking of RHEED intensity changes and measuring the rate of oscillations for quantitative determination of growth rate. It also has image analysis capabilities such as capturing and profiling. The software program takes input from a high sensitivity CCD digital camera. All components are outside the thin film deposition system hence retrofitting this package to existing machines is very simple.

Perkin-Elmer Model 06-190 10keV HEED Gun

Perkin-Elmer 20-330 RHEED Gun Control

K-Space (KSA) BP-M1 CCD Camera

KSA 300/400 Software

INFICON Transpector TH100 F&M Quadrupole Residual Gas Analyzer

Transpector Ware V2.0 Software

ISA RIBER Model 28800 Loading/Introduction Chamber

VME 38 Roughing Pump Valve

Thermionics Northwest EM201.8-8-8B XYZ Manipulators

ISA RIBER TLTM 63/700 Linear and Rotary Motion Feedthrough

Diagram of TLTM 63/700 is available here: TLTM 63/700

ISA RIBER PEG-1000S Titanium Sublimation Pump

ISA RIBER Model 304-4 Titanium Sublimator Power Supply

MTU Titanium Sublimation Power Supplies
















ISA RIBER Mobel JBA 307 S0/2 Electrometers

MTU JBA 307 Series Electrometers

Electrometers display the current produced by the Bayard-Alpert (B-A) ionization gauges located in the main and load-lock chambers in meaningful units (torr). See this for a brief explanation of the theory of operation of B-A ionization gauges. The gauges installed in the MBE are the UHV nude type. The electrometers also serve as the control interface for the B-A ionization gauges. Overpressure protection is included, shutting off power to the B-A ionization gauge when the measured pressure exceeds approximately 10-3 torr. See this manual for operation of the electrometer.

Operating the Electrometers and B-A Ionization Gauges

DO NOT attempt to turn on the gauges when the pressure in the chamber is greater than 10-4 torr.

  1. Turn on the electrometer by pressing the ON button.
  2. Activate power to the B-A ionization gauge by pressing either IG1 or IG2 buttons (there are two cathodes in each gauge to provide failover).
  1. Deactivate power to the B-A ionization gauges by pressing the illuminated IG1 or IG2 button.
  2. Turn off the electrometer by pressing the illuminated ON button.

Degassing the B-A Ionization Gauge

If the chamber has become badly contaminated as a result of extended exposure to atmosphere or other event, or if the B-A gauges have been in continual operation for a very long period of time, the anode will likely need to be degassed. Press the DEGAS button on the electrometer to activate the degas circuit and leave in this mode for 10-15 minutes. While degassing, the reading on the electrometer will vary, potentially quite a lot, until condensed gas is driven from the anode.

Standard Operating Procedure

The standard operating procedure for the MBE system is described below in details. The steps should be followed exactly during every sequence.

Note: Bullet points should be followed sequentially, as sub-steps.

Venting Load-lock

  1. Ensure that the gate valve between the main and load-lock chamber is closed
  2. Turn off the load-lock ion gauge
    • Press the IG1 button on the gauge panel
  3. Close the pneumatic gate valve on the load-lock TMP outlet
  4. Unscrew the load-lock chamber exchange window
  5. Wait for 5 minutes after the ion gauge has been turned off to allow the filament to cool
  6. Check the pressure in the N2 regulator
    • This should be ~ 20 psi
  7. Set the UHP N2 to the vent line (plastic piping)
    • The valve handle has a pointed end, to indicate direction of gas flow
  8. Open the vent valve

Note: Make sure that the ion pumps, the TMP pumps, and the ion gauge in the main chamber are not increasing. This will indicate a leak. Close the valve if the TMP loads increase, or if there is a large fluctuation in the main chamber ion gauge reading, or ion pump readings, close the vent valve.

  1. Once up to atmosphere, retrieve or input the sample holders
    • Sample holders can be release by rotating by hand
  2. Close the N2 vent line while the door is loosely shut (unlatched, but the load-lock/window seals should be touching)
  3. Lightly fasten the exchange window, to maintain a N2 environment in the load-lock chamber

WARNING: Do not latch the exchange window until the N2 vent line is closed. The internal pressure buildup can severely damage the system.

Pumping Down the Load-Lock Chamber

Note: This procedure assumes that substrates are being loaded into the load-lock chamber, for transfer. If the load-lock is in a vented state (correct system section isolation is set out in "Venting the Load-Lock"), and no substrate loading is necessary, proceed from step 8 on.

  1. Unlatch the load-lock exchange window
  2. Open the UHP N2 vent line
  3. Open the exchange window to mount the sample holders
  4. Mount the sample holder(s)
    • If loading onto the substrate transfer arm, insert the pins closest to the sample holder face into the arm brackets (the holder face should be facing into to transfer arm)
    • The load-lock can accommodate two sample holders
  5. Shut the exchange window without latching
  6. Close the N2 vent line while the door is loosely shut (unlatched, but the load-lock/window seals should be touching)
  7. Lightly fasten the load-lock exchange door
  8. Turn off the ion pump
    • Flip the power switch up, to the off position
  9. Close the backing lines to both the load-lock and main chamber TMPs
  10. Open the rough valve with a ¾” wrench, and then fully by hand
  11. Close the rough line once the rough pressure is <30 mtorr (measured using the convection gauge on the main chamber TMP)
  12. Open the backing line for the load-lock TMP
  13. Open the gate valve for the load-lock pumps
  14. Once the pressure in the backing line is <20 mtorr turn on the load-lock ion gauge
  15. Turn on the load-lock ion pump
  16. Open the backing line for the main chamber Turbo
  17. Let the load-lock pump down until the pressure is at least 5x10-7 torr, which is the required pressure to do a sample transfer.


Sample exchange from Main Chamber to Load-Lock

  1. Ramp the substrate down temperature from the deposition temperature
    • Set the substrate temperature controller to 0oC
  2. Allow the substrate holder to cool down from the deposition substrate temperature
  3. Make sure the load-lock and main chamber have similar pressures
    • The pressures can differ by two orders of magnitude, from 10-9 to 10-7 torr for the main chamber and load-lock, respectively
  4. Open the load-lock to the main-chamber by opening the gate valve
  5. Adjust the substrate heater angle to approximately 135º with the adjustment dial
  6. Turn on the flashlight attached to the main chamber window, next to the adjustment dial, to allow sight of the transfer
  7. Push in the transfer arm
  8. Align the substrate holder pins with the receiving brackets on the transfer arm
    • The heater might need to be changed to a different angle

Note: Move the transfer arm away from the sample holder before changing the angle, so that they do not collide.

    • The pins and brackets are not symmetrical, so the holder may need to be rotated to align all the pins
  1. The arm should push on with no friction
  2. Rotate the substrate holder until the pins are unloaded from the heater brackets, and the transfer arm can be retracted without friction

Note: Before disengaging the transfer arm, release the rubber belt connecting the rotator motor to the external substrate rotator, to relieve tension built up in the transfer.

  1. Pull the transfer arm into the load-lock
  2. Close the Load-Lock to the main chamber by closing the gate valve
  3. Wait for sample to cool to a safe handling temperature before attempting to remove from load-lock

Running the Plasmatron

The plasmatron is used to energize either ultra-high purity (UHP) gases of N2, O2, or Ar for the growth of semiconductors. This procedure details the use of N2 but is not exclusive to N2; it is detailed because of the Mosaic project involves the growth of nitrides.

Turning on the Plasma

  1. Turn on the water for the plasmatron
  2. Turn on the oscilloscope
  3. Turn on the plasma chamber pressure monitor
  4. Turn on the radio frequency (RF) power supply
  5. Set the RF power to 800 W
  6. Ensure that the UHP N2 is set to the plasmatron
  7. Turn off the main chamber ion pump
  8. Turn off the main chamber ion gauge
    • Press the IG1 button on the main chamber gauge panel
  9. Turn off the residual gas analyzer (RGA)
  10. Close the backing line for the load-lock turbo-molecular pump (TMP)
  11. Bleed out the manifold by opening the leak valve
    • Limit the pressure to 10 Pa
  12. Close the leak valve once the manifold has been evacuated
  13. Open the N2 valve on the gas manifold
  14. Slowly open the leak valve until the plasma chamber pressure monitor gives a low reading
  15. Open the leak valve steadily until the pressure is 60 Pa
  16. Strike the plasma
    • Press the RF on button until the plasma strikes (successful striking can be noted on the oscilloscope)
  17. Quickly drop the pressure, and tune to the desired pressure
    • The current desired pressure is at 3.2 Pa
  18. Wait until the power has decreased to a stable power (takes about 30 mins)
    • The usual procedure excludes this step. Taking optical emission spectroscopy determined that there was no change in the atomic-to-molecular nitrogen ratio.

Plasma Strike with Ar (if striking with N2 does not work)

  1. Close the N2 manifold and set the UPH Ar line to the plasmatron
  2. Bleed out the manifold
  3. Open the Ar valve on the gas manifold
  4. Slowly open the leak valve until the plasma chamber pressure monitor gives a low reading
  5. Open the leak valve steadily until the pressure is 60 Pa
  6. Strike the plasma

Note: You might have to go to higher power or throttle the gate valve on the main chamber TMP to allow for high pressures.

  1. Once the plasma is struck close the Ar on the manifold and set the pressure to 10 Pa
  2. Once the pressure has reduced to 3 Pa fill the manifold with N2 to 10 Pa
  3. Repeat steps 7 and 8 four times
  4. Open the N2 manifold valve fully while closing the leak valve to keep the pressure below 10 Pa

Plasmatron Wattages for Certain Pressures

Pressure (Pa) Power (W)
2 414
2.5 337
3 326
4 327
5 332 (stabilizes at 275 after 30 mins)
6 350
7 363
8 380

Turning off the Plasma

  1. Close the N2 manifold valve
  2. Close the leak valve
  3. Turn off the RF power
  4. Turn on the ion gauge
    • Press the IG1 button on the gauge panel
  5. Turn on the ion pump
  6. Open the backing to the load-lock TMP
  7. Turn on the RGA
  8. Turn off the plasmatron water supply


Substrate Cleaning

For sample cleaning, follow the instructions next to the fume hood.

If required, more de-ionized water can be obtained in Room 414. Run the faucet for a few minutes to clear the line before filling the bottle

Large bottles of solvents are stored in the cabinet below the fume hood. These are used to refill the smaller bottles used in the cleaning process.

Silicon substrates are located in the bottom drawer of the tall, tan cabinet next to the fume hood. Aluminium nitride substrates are located in the grey substrate box atop this cabinet.


Reflective High Energy Electron Diffraction (RHEED) System

Warmup

  1. Turn on the power to the RHEED system
  2. Ensure that the Current switch is set to Filament (Amps)
  3. Raise the current to 2.5 Amps, in increments of 0.5 Amps/minute
    • Turn the filament dial slowly
  4. Once the current is 2.5 Amps, set the Current switch to Emission (ma)
  5. Raise the current to 1 ma, in two increments of 0.5 ma/minute
    • Turn the filament dial slowly
  6. Once the current is 1 ma, turn on the Beam Voltage (KV)
    • Move the switch below the dial two clicks vertically, from off to on
  7. Raise the voltage to 10 KV, in increments of 1 V/minute
    • The voltage is read by the listed number left of the measuring line, on the outside ring

Turning off the RHEED

  1. Turn down the current to 0 ma (when the Current switch is switched to Emission)
  2. Set the Current switch to Filament
  3. Turn down the current to 0 Amps
  4. Turn down the Beam Voltage dial to 0 KV
  5. Turn the Beam Voltage switch to off
  6. Turn the RHEED power switch to off

Growth of AlN on Si<111>

This process assumes that the sample is already in the MBE main chamber and the sample is at 135o.

Italicized text indicates inconstant temperatures, rates, and deposition durations.

Note: Watch the effusion cell voltage supply during the growth. If the "overvoltage" light turns on, turn the respective voltage supply off, then back on. Otherwise, the temperature will plummet, to the possible damage of the crucible in the given effusion cell.

  1. Heat the Al source to 1200oC in steps of 50oC, Al is kept at 850oC
  2. Leave the Al at 1200oC for half an hour to outgas the source
  3. Raise the window shield
  4. Make certain the QCM water is on
  5. Insert the QCM
    • Use the provided drill to screw in the monitor, clockwise
  6. Open the Al source, and measure the rate
    • The QCM monitor real-time rate graph should be stable
  7. Reduce the Al cell temperature to the desired temperature for the required rate ~0.45 Å/s
  8. Ramp the substrate up to 920oC
  9. Let the substrate stabilize at 920oC for 10 mins to burn off the native oxide
  10. Reduce the substrate temperature to 700oC
  11. Remove the QCM
  12. Turn the substrate rotator on
  13. Deposit 10 secs of Al on the Si substrate
    • Move substrate from 135o to 295o
  14. Start the plasmatron (see pg. 4, Running the Plasmatron)
  15. Start the RHEED (see pg. 8, RHEED System Warmup)
  16. Once the plasmatron has had about 30 mins to stabilize move the substrate into the growth position (295o) to start the AlN
  17. Set the substrate temperature to 870oC
  18. After 1 hour return the substrate to 135o
  19. Turn off the plasmatron (see pg. 5, Turning off the Plasma
  20. Insert the QCM to measure the rate
  21. Ramp the substrate heater to 0oC
  22. Take a final RHEED
  23. Turn off the RHEED (see pg. 8, Turning off the RHEED)

Venting main Chamber

  1. Close the manual valve to the main chamber
  2. Close the pneumatic valve to the load-lock
  3. Shut down both of the ion gauges
  4. Shut down the ion pump and the titanium sublimation pump
  5. Unscrew the latch on load-lock chamber door (this will prevent positive pressure build up while venting with Nitrogen)
  6. Wait for 5 minutes after the ion gauge has been turned off (this is required for cooling down the filament)
  7. Check the pressure in the Nitrogen cylinder (It should be around 20 psi). Turn the cylinder knob toward the N2 flowing pipe. Flow nitrogen slowly into the chamber while keeping an eye on how much load the pump is taking
  8. Once the chamber is vented the load-lock door will open up

Baking out the system after opening

If the main chamber of the MBE is open to atmosphere to replace the QCM crystal, replace or refill the effusion cells, modify the plasmatron, or any other maintenance, the system will need to be baked to drive off water vapor.

Running the 6 filament Ti sublimator (main chamber)

  1. Ramp up the current to 30-40 Amps at 10 amp/steps
  2. Run the Ti sublimators for 3 hours at a time

After a bake out the system will be in an idle state where the cryo shrouds are empty of water and only the ion pumps will be running. The cryo bypass is removed to let out steam during the bake out. The pressure of the Load-Lock (4.1×10-7 torr) and the Main Chamber (4.8×10-10 torr) will be monitored by ion gauges. All the effusion sources will normally be cold.

Setting up the system

  1. Connect the water bypass for the cryo shrouds
  2. Each cryo panel will need to be refilled with water and ensure that we do not put air bubbles into the main water supply for the building and adjacent labs by following the steps (WARNING: Monitor pressure to make sure it does not increase as this might mean a water leak in the chamber, also check for leaks on connectors)
    • Open the main supply
    • Open the air purge for the return
    • Open the top shroud return
    • Open the top shroud supply
    • Wait until the water comes out with out air bubbles
    • Close the return and supply for the top shroud
    • Repeat the process for the bottom shroud
    • Once both shrouds are bleed and fill of water the return and supply can be opened
  3. The next process is to get the turbo molecular pumps (TMP) back online
    • Turn on the scroll pump in the corner of the lab under the boxes
    • Wait until the backing line for the Load-Lock and Main Chamber TMP is down to 15 mtorr
    • This can be found on the convection gauge that is mounted on the Main Chamber TMP
    • Turn on the fan to the Load-Lock turbo
    • Turn on the Load-Lock TMP
    • Leave the backing line to the Load-Lock TMP closed until TMP is up to full speed to not dump high vacuum into the ion pump
    • A click should indicate when the line is fully open

Roughing System

BOC Edwards QDP Drystar Roughing Pump

Roughing is provided by a BOC Edwards QDP Drystar vacuum pump. The foreline has three connection points, backing for each of the turbomolecular pumps and roughing at the load-lock chamber. All connection points are individually valved with manually operated Isa Riber isolation valves.

The roughing pump operates continuously while the system is under vacuum.


ISA RIBER JTC 6 T Thermocouple Gauge

ISA RIBER JTC 6 C Power Supply

Component Suppliers

ISA Riber Company - Riber's Website

SVT Associates, Inc. - SVT's Website

k-Space Associates, Inc. - KSA's Website

TLI Enterprises, Inc. "Thermionics" - Thermionic's Website

Inficon - Inficon's Website

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