|
Mainly
used for solid state physics and applied physics experiments.
Electrostatic accelerator, Van de Graaff type.
Single stage-Belt
charging system.
Maximum terminal working voltage 2.5 MV.
Available accelerated ions: 1H,
4He single charged
Continuous beam.
Maximum Ion Energy: 2.5 MeV
1 experimental hall; 5 beam lines among which one dedicated to a microbeam
facility. |
Mainly
used for interdisciplinary research, neutron physics research and
advanced educational purposes.
Electrostatic accelerator, Van de Graaff type.
Single stage-Belt charging system.
Maximum terminal working voltage: 7 MV.
Available accelerated ions:
1,2H,
3He, 4He single and double charged
D,
15N double charged
Continuous and pulsed beam.
Maximum Ion Energy:
7
MeV for single charged
14
MeV for 4He++
8
MeV for 15N++
1 experimental hall; 7 beam lines. |
|
Mainly
used for fundamental heavy-ions nuclear physics experiments.
Electrostatic accelerator, Van de Graaff type.
Double stage with two stripper stations (one at the terminal and one
in the High Energy stage) - Laddertron charging system.
Maximum working voltage: 15 MV.
Available accelerated ions range from 1H to 197Au
(see list with
available currents).
Continuous and pulsed beam.
Energy:from 30 MeV/AMU for 1H to about 1.5 MeV/AMU for 197Au.
3 experimental halls; 10 beam lines.
At present the Tandem-XTU acts also as injector for ALPI. |
Mainly
used for fundamental heavy-ions nuclear physics experiments at intermediate
energy.
Linear superconducting quarter-wave resonant cavities accelerator. At
present ions are injected by Tandem
Superconducting material: Lead and Niobium.
Accelerated Ions: from 28Si to 197Au.
Energy: about 20 MV multiplied the ion charge state.
The total output energy of ions emerging from the Tandem-Alpi complex
is the sum of injection energy (Tandem acting as injector) and ALPI
energy. Hence the total energy of the complex is about 35 x charge
state (MeV).
Experimental halls and beam lines: the same ones of Tandem-XTU. |
