30KeV Electron Gun: Beam Spot Size: 90micro meter dia. Maximum
Filament: 0.1mm dia. Tungsten Wire (hairpin-shaped)
Wehnelt: Self Bias
Focus Lens: Air Core Solenoid Coil Lens
Deflection Lens: Troidal Coil Lens
Axial Alignment Mechanism: Alignment for Filament and Wehnelt
Insulation Voltage: DC30KV
Working Pressure: <10-4Pa to 10-9Pa
Max. Bakeout Temperature: 200 degrees C
Mounting Flange: ICF70
Dimensions: 100mm dia. x 401mm long
(501mm long with a connector inserted)
30KeV E-GUN POWER SUPPLY: Acceleration Voltage: 0 to -30KeV Constant Voltage Supply
( Ripple 0.03% Maximum)
Beam Current: 0 to 160 micro ampere
Filament Voltage: 0 to 5V Constant Voltage Supply
(Ripple 0.05% Maximum)
Filament Current: Max. 2A
Deflection Lens Supply: 1A Constant Current Source(plus or minus1V)
(Ripple 0.05% Maximum)
Focus Lens Supply: 0 to 1.5A Constant Current Source(0 to 22V)
(Ripple 0.05% Maximum)
Input Power: 200V, 220V, 230V, 240V
Dimensions: 480mm x 199mm x 500mm (cable +100mm)
Safety Feature: High Voltage Interlock
Others: RoHS-ready
Reflection High-Energy Electron Diffraction (RHEED) has become widely known as an essential method for real-time observation of crystal growth. RHEED can be used to analyze film surfaces in either a static mode for existing materials or dynamically as film growth evolves. This makes RHEED an exceptionally valuable tool for investigating structures in Molecular Beam Epitaxy (MBE).
In general, RHEED is a method for investing the structure of crystal surfaces. A high-energy electron beam(10-30KeV) is directed at the sample surface at a low incident angle(1-2°).The electrons are diffracted by the crystal structure of the sample being investigated and then projected on a fluorescent screen mounted opposite the electron gun. The characteristic pattern of the impinging electrons is a series of streaks. The distance between the streaks is an indication of the surface lattice cell size.