The Siam Photon Source (SPS) is an electron accelerator complex consisting of a 40 MeV linear accelerator (LINAC), a 1.2 GeV booster synchrotron (SYN) and a 1.2 GeV electron storage ring (STR). The elctrons are produced by a thermionic electron gun then accelerated by 2856 MHz high power microwave in the linear accelerator. The 40 MeV electrons are transported by the low energy beam transport line (LBT) to the booster synchrotron and accelerated to 1.2 GeV by 118 MHz Radio Frequency wave in the RF cavity of the booster synchrotron. The 1.2 GeV electrons are transported by the high energy beam transport line (HBT) to the storage ring.
Components of Siam Photon Source
1. Electron gun
Electron beam is produced by the electron gun via thermionic process, that is, the gun filament is heated by the applied electric current causing electrons to be released. These electrons are then ‘pulled’ toward the linear accelerator by an applied electric field.
2. Linear accelerators
Electron beam from the electron gun is then accelerated by two 20 MeV (20 million electron volts) linear accelerators, or linacs for short. After passing through the two accelerating structures, the 40 MeV electrons then enter the booster synchrotron via the low-energy beam transport line (LBT) for further acceleration.
3. Booster synchrotron
The booster synchrotron accelerates 40 MeV low energy electrons to 1.2 GeV (1.2 billion electron volts). Each round an electron circulates in the booster ring it gains incremental energy through applied radio wave inside the radio-frequency (RF) cavity. To attain 1.2 GeV energy electrons must circulate approximately 4 million turns in the booster, although the whole process lasts merely 0.6 seconds.
4. Storage ring
The 1.2 GeV electrons are then sent to the storage ring. After this beam injection process the electrons are stored in the ring to produce synchrotron radiation. Each time electron passes through a bending magnet or an insertion device, i.e. a magnet specially designed for the production of higher-energy and/or higher-brilliance or specifically polarized synchrotron light, it loses a small portion of its energy in the form of electromagnetic radiation, i.e. synchrotron radiation. This portion of energy is then recovered when the electron passes through the RF cavity in the ring.
5. Photon beamlines
Synchrotron light is carried to the experimental stations via photon beamlines. Two most important components of a photon beamline are the monochromator and focusing elements. Mirrors are used to focus the photon beam to a small area of interest while retaining the available photon fluxes. Monochromator is used to select the photon energy suitable for a particular experiment. Each beamline has different components and setups depending on the photon energy range to be used and type of experiment to be carried out.
6. Experimental stations
Experimental station is where the sample to be studied is located. A great number of measurements and experiments can be set up to utilize the generated synchrotron radiation. Data from the interaction processes between light and matter is then collected for subsequent analyses. Measurement techniques utilizing synchrotron radiation have been proven to be invaluable in researches in a wide variety of disciplines, including physical science, biological science, materials science, agriculture, archaeology, environmental science, among others.
The Siam Photon Source electron beam energy is 1.2 GeV, and the electron current injected for each operation cycle (filling) is 150 mA. At present the beam emittance is 41 nm-rad, and the beam lifetime is approximately 12 hours at 100 mA. Currently, there are four insertion devices (IDs) installed in the ring. U60 permanent magnet planar undulator, 2.2 Tesla multipole wiggler (MPW), 6.5 Tesla superconducting magnet wavelength shifter (SWLS) and the latest 3.5 Tesla superconducting magnet multipole wiggler (SMPW) occupied all the available space in the ring. Thus the machine can produce wide range of photon energy from IR to hard x-rays for SLRI users.
beam injection process