BlochDocs
  • The Bloch beamline
    • Overview
      • Ring
      • EPU
      • M1
      • Monochromator
      • M3
      • Exit slits
      • M4
    • Energy resolution
    • Flux
    • Spot size
  • How to run the beamline
    • Control GUIs
      • How to launch control GUIs
      • Beamline control panel (Windows computer)
      • M1 pitch corrector (Windows computer)
      • Energy panel (Linux computer)
    • Optimizing flux
  • Sample mounting & cleaving
    • Sample plates at BLOCH
    • Mounting considerations
    • Gluing
    • Physical mounting
    • Tape cleaving
    • Top-post cleaving
  • Fast entry source ports
    • Calculating length requirements
  • Getting your data
    • USB stick
    • SFTP
      • SSHFS (recommended for mac/linux users)
      • Graphical clients
  • Food options
    • Vending machines
    • Coffee
    • Supermarkets
    • Food trucks
    • Nearby cafes and restaurants
    • Delivery
  • Basler sample cameras
    • Starting a video stream
    • Crosshairs
    • Frame errors
  • Data analysis
    • pesto library (Python / Jupyter)
    • Igor Pro
      • Igor macro: DA30 chunkloader
      • Igor macro: ARPES Analysis
      • Igor macro: ESpectroscopia
      • Igor macro: BLOCHFit
    • SES
  • Example data
    • A-endstation (Scienta / SES)
    • B-endstation (SPECS / Prodigy)

High-resolution 'A' endstation

  • Loadlock
    • Pumpdown time
  • ‘Main’ Preparation Chamber
    • Sample receivers
    • Sputtering
    • Heating
      • Direct current heating
      • Electron-beam heating
      • Cooling
  • ‘Secondary’ Preparation Chamber
    • Wobblestick
    • Sample receivers
    • Moving the manipulator
    • Sputtering
    • Heating
      • Direct current
      • Resistive
      • E-beam heating
    • Quartz crystal thickness monitor
    • LN2 cooling
  • Gold deposition
  • Radial distribution chamber (‘UFO’)
    • Cold transfers
  • Analysis chamber
    • Maximum countrate
    • Sample camera
    • Control GUIs
      • How to launch control GUIs
      • Manipulator control (Windows computer)
      • ‘Automap’ Windows computer)
      • Temperature control panel (Windows computer)
      • Trendplots (Windows computer)
      • Launcher panel (Linux computer)
      • Carving panel (Linux computer)
  • Using SES to measure
    • Preliminary notes about SES:
    • Deflector ARPES scans
    • 1D manipulator scans (e.g. Fermi surface maps)
    • Time dependent scans
    • Photon energy scans
    • 2D manipulator maps (e.g. X-Y spatial maps)
  • DA30-L electron analyzer
    • Deflection mode
    • Focusing
    • Analyzer slit selection
    • Lens modes and restrictions
    • Fixed vs. scanned/swept acquisition mode
    • Mesh suppression
    • Angular resolution
    • Energy resolution
  • Carving 6-axis manipulator
    • Specifications
    • Transferring samples
    • Sample biasing
    • Connections and grounding
    • Heating and cooling
      • Temperature calibration and stabilization
  • Stinger closed cycle cryostat
    • Overview
    • Technical details
  • Alkali deposition
  • LEED
    • Secondary Preparation Chamber
      • Recommended settings
    • Main Preparation Chamber
  • Sputtering
    • Sputter beam characteristics
    • Sputtering procedure
  • Pyrometer
  • VT-XA STM
    • Specifications
    • Transferring samples
    • Cooling/Heating
    • Tip preparation tool
    • XY calibration and lattice size measurements
    • Tunneling spectroscopy
      • Setup
      • Minimizing capacitive crosstalk
      • Parameter values
      • Acquiring and processing STS
      • Energy resolution
      • Examples

Spin-resolved 'B' endstation

  • Analysis chamber
    • Sample camera
    • Control GUIs
      • How to launch control GUIs
      • Manipulator control (Windows computer)
      • ‘Automap’ Windows computer)
      • Temperature control panel (Windows computer)
      • Trendplots (Windows computer)
      • Launcher panel (Linux computer)
  • Using Prodigy to measure
    • Device controls panel
    • Experiment editor panel
      • Configuring measurements:
      • Acquiring and saving measurements:
    • Visualization panels
      • Viewing 3D deflector maps:
    • Spatial mapping
    • Optimizing spin detector lens voltages
      • Finding the optimized values
      • Using the optimized lens voltages
  • Phoibos 150 analyzer w/ VLEED
    • Deflection mode
    • Spin detector
      • Overview
      • Measurement principle
      • Angular and energy resolution
    • Analyzer slit selection
    • Spin aperture selection
    • Energy resolution
  • How to analyze spin data
    • Preliminaries
      • Polarization terminology
    • The spin detector at Bloch
      • Analysis
      • Coordinate systems
      • Example: WSe2
      • Example: Au(111)
  • LEED
    • Main preparation chamber
    • ‘Prep top’

For beamline staff

  • Troubleshooting
    • On-call support options
    • Icepap
      • Closed loop errors
      • Overcurrent errors
    • SES
  • NEG pumps
  • Gas lines
    • Procedure for filling gas lines
      • 1. Attach a regulator to the bottle and gas line
      • 2. Pump the line to low vacuum
      • 3. Pump the line to high vacuum
      • 4. Open the bottle and fill the line
      • 5. Remove the bottle
    • Mini-mix style bottles
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