introducing the second
generation of Atom Sources, Ion Sources and Atom/Ion Hybrid Sources.
tectra Gen2 Plasma
Source
Since 1997 tectra has produced more than 50 Plasma Sources as Atom Source, Ion Source and Atom/Ion Hybrid Source. Based on this experience we now present the second generation sources, the Gen2.
New Features of Gen2 Plasma Source:
- high performance direct microwave coupling (without need of tuning)
- improved microwave guide with minimised attenuation
- higher plasma density resulting in higher ion current
- bakeable magnets, still on air side, with closed cooling loop
- more compact, space saving air side setup
- Al2O3 plasma cup now standard with higher yield of secondary electrons and better resistance against aggressive gases
- additional display of extraction current to optimise the beam shape
- improved stability of microwave generation
- new grid supply for more versatile, wide range ion energies of 20eV - 2keV with same grid set
- LED to show if plasma is on or off
pdf
version of data sheet (206kB)
Plasma Source
Atom Source, Ion Source and Atom/Ion Hybrid Source
The tectra Plasma Source* is a multi-purpose source which can easily be user configured to produce either atoms or ions and finds uses in a wide range of HV and UHV applications. By easy exchange of the beam optics the source can be configured to operate in several distinct modes. The main modes are Atom Source, Ion Source and Atom/Ion Hybrid Source. Besides delivering different species (atoms, ions, radicals) the Plasma Source covers the complete energy range from neutral thermal atoms to above 1.500eV. The shape of the beam and current densities can be altered by using different beam optics.
A plasma
is created in a coaxial waveguide
by evanescent wave coupling of microwave energy at 2.45GHz.
The plasma
is further enhanced by the ECR action of a quadrupole magnetic field
producing
an extensive surface in the plasma on which electron cyclotron
resonance
at the given microwave frequency takes place.
tectra Plasma Source + Power Supplies
(new pictures
coming soon)
Key
Features:
|
Suitable for use with most gases including reactive gases such as oxygen, chlorine, hydrogen, nitrogen etc. |
|
Factory set. Simply turn the plasma on and off. |
|
The extraction optics are designed to be quickly and easily exchanged allowing users to customise their source to suit a particular combination of sample size, working pressure and current density. Easily exchanged apertures enable beam diameter, gas load and atom flux to be optimised. |
|
new bakeable ECR magnets allow simple bekeout preparation by just undoing 4 screws. The magnets are still on the air side on a closed cooling loop. Hence no sintered material is in-vacuum. |
|
Alumina plasma cup as standard with higher yield of secondary electrons and better resistance against aggressive gases such as Oxygen |
|
the air side envilope sizes are brought to a minimum of just 258mm from flange (knife edge side) to case end (see schematic) |
Integration of the robust microwave generator and the ion source, mean that no tuning of the source is required and there is no waveguide to construct or install.
Due to the evanescent wave coupling, no electrodes are present in the plasma i.e. no filaments or other metal. The plasma is entirely surrounded by alumina or other dielectric materials e.g. BN. Therefore the source is also suitable for use with reactive gases such as oxygen and hydrogen. A selection of apertures and conductances allows the optimum balance between gas flow, working pressure and beam current to be achieved.
The source
is designed as a true UHV source
making it suitable for use in UHV applications such as MBE as well as
sputtering
and other HV processes. Stainless steel, OFHC copper, BN, alumina and
Kapton
are the only materials exposed to the vacuum. All joints are welded.
The
magnets and all microwave parts are easily removed for bakeout at
temperatures
in excess of 200°C.
Modes of operation:
Four distinct modes of operation are possible with this source depending principally on the beam optics which are fitted. The beam optics are constructed as one piece and may easily be exchanged by the user to allow the source to be used in another mode. The parts necessary to convert the source from one mode to another are all retrofittable by the user and can be added at any time in the future as research needs change.
(1)
Atom source
The specially
designed aperture plate
inhibits ions from escaping from the plasma, yet allows reactive
neutrals
to escape and form the dominant beam fraction. The emitted particles
are
largely thermalised through multiple collisions on passing through the
aperture. These neutrals have proven to be very effective in
low
damage surface treatments such as nitridation and oxidation(1,2). The
further
addition of an ion-trap option can completely remove the residual ion
content
from the beam where this may be of concern.
(2)
Downstream plasma source
With this aperture
plate a larger proportion
of the charged particles in the plasma are allowed to escape. There is
no active extraction or acceleration of the charged particles but a
considerably
higher ion current reaches the sample in this mode as compared with the
atom source above. Samples mounted a few centimetres from the source
are
said to be “downstream” of the ion source and away from the
most
energetic species. Ion energies are defined by the intrinsic plasma
potential
and are around 25eV.
(3)
Hybrid source
The beam optics in
this mode combine the
atom source aperture plate with electrodes providing active extraction
of ions from the plasma. With no voltage applied to the electrodes the
source functions like the atom source at (1) above. With
voltage
applied to the electrodes, ions with controllable energy can be added
to
the atom beam. Total beam current is in the ~50µA range.
Using
this mode the advantages of both a low kinetic energy, chemically
reactive,
atom beam and a much higher kinetic energy, highly anisotropic ion beam
may be explored.
(4)
Broad Beam Ion Source
Dual or triple high
conductance grid electrodes
are used to produce the broad beam ion source mode. For
sputtering
applications, current densities at ~120mm of 2mA/cm² (focused optics)
with ion energies of 1.3keV can be obtained while for deposition
assistance
(Ion Assisted Deposition or Dual Ion Beam Sputtering) the beam energy
can
be reduced to less than 100eV with current densities still in the
0.05mA/cm²
range.
Atom
Source Mode Applications:
- Nitriding e.g. GaN, AlN, GaAsN, SiN etc.
- Hydrogen cleaning, hydrogen assisted MBE.
- Oxidation e.g. ZnO, Superconductors, Optical coatings, Dielectrics.
- Doping e.g. ZnSe
Ion
Beam Mode Applications:
- Ion beam assisted deposition (IBAD) for both UHV and HV processes
- Sputter deposition and dual ion beam sputtering
- Sputter cleaning / surface preparation in surface science, MBE and HV sputter processes.
- In-situ etching e.g. Chlorine
Specifications
a) General
| Vacuum compatibility: | Fully UHV compatible |
| Bakeable: | >200°C |
| Microwave power: | 250W max at 2.45GHz |
| Magnet type: | Permanent rare-earth. Removeable for bakeout without breaking vacuum |
| Mounting: | NW63CF (4.5"OD) |
| In vacuum length: | 300mm (custom lengths possible): In vacuum diameter max = 57mm |
| Beam diameter: | ~25mm at source (narrower beams also easily produced) |
| Plasma cup: | Alumina |
| Aperture: | Alumina or Boron Nitride |
| Gas flow rate: | 0.01-100sccm depending on aperture selected |
| Working pressure: | ~10-7 Torr to 5x10-3 Torr depending on aperture, pump and application - please contact tectra to discuss your application. Differential pumping option available |
| Working Distance: | 50mm-300mm. 150mm typical |
| Cooling: | Fully water-cooled (including magnetron) |
| Power
supplies:
Microwave Grid supply* * Ion and Hybrid Source only |
19” rack mount. 3U height. 230VAC, 50Hz or 115VAC, 60Hz 19” rack mount. 3U height. 230VAC, 50Hz or 115VAC, 60Hz |
b) Atom source
| Atom flux | >2x1016 atoms/cm2/s at 10cm |
| Beam divergence: | ~ 15° half-angle typical |
| Gases | Nitrogen, Oxygen, Hydrogen (any most other non-condensible gases) |
| Working pressure: | 1x10-8 mabr to 1x10-1 mbar typical (using 500l/s pump) and depending on selected grids, pump, optional differential pumping and gases. |
| Working distance: | <50mm to >300mm (150mm typical) |
| Options: | (1)
Residual Ion Trap
(2) Differential pumping (3) Ion source retrofit kit (4) Plasma igniter |
c) Ion source
| Ion current: | 0 - 20mA (max.). Total beam current measured at 15cm |
| Ion current density: | >2mA/cm2 at 1.3keV and >0.05mA/cm2 at <100eV at 120mm distance. |
| Ion energy: | 25eV - 2000eV |
| Beam diameter: | ~25mm at source (narrower beams down to 1mm also easily produced) |
| Extraction grids: | Molybdenum
(Graphite optionally)
Focused and collimated beam grid sets available |
| Gas flow rate: | 5-10sccm typical (lower and higher flow ratespossible) |
| Working pressure: | 1x10-8 mabr to 1x10-1 mbar typical (using 500l/s pump) and depending on selected grids, pump, optional differential pumping and gases. |
| Working distance: | <50mm to >300mm (150mm typical) |
| Options: | (1)
Immersed filament beam neutralisation
(2) Plane, focused and divergent grid sets made from molybdenum or pyrolytic graphite (3) Differential pumping (4) Shutter (5) Faraday Cup integrated in shutter |
Options
Plasma Source with differential
pumping
for low pressure
operation and with shutter
Plasma
Source with differential pumping
for high pressure
operation
special Atom aperture for reduced flux/small samples
Atom aperture with quartz collimator
tube
special Atom
aperture for reduced flux/small
samples
Elongated version with second gas inlet
References:
- The role of neutral oxygen radicals in the oxidation of Ag films. A. A. Schmidt, J. Offermann and R. Anton. Thin Solid Films 281-282 (1996) 105-107.
- Design and performance of a versatile cost-effective microwave ECR plasma source for surface and thin film processing. R.Anton, T. Wiegner, W. Naumann, M. Liebmann, C. Klein, C. Bradley. Rev.Sci.Instr. Feb 2000
tectra GmbH reserves
the right to alter specifications without notice.
*developed in collaboration with Prof. Dr. Anton, University of Hamburg, Inst. fuer Angewandte Physik