| Paper | Title | Page |
|---|---|---|
| TH5PFP029 | Optical Measurement System of Laser-Cooled Mg Ion Beam | 3257 |
|
||
|
Funding: This work is supported by Advanced Accelerator Development Project of MEXT and the Global COE program "The Next Generation of Physics, Spun from Universality and Emergence". Transverse laser cooling experiments of 24Mg+ beam have been carried out at S-LSR, which is a small ion storage and cooler ring. According to a simulation, it is expected that under such a condition as the difference of synchrotron and betatron tunes is near integer, synchro-betatron coupling occurs and transverse laser cooling will be achieved*. In order to confirm this situation, the horizontal beam size and momentum spread are measured optically with CCD camera and PAT (post acceleration tube), respectively**,***. CCD camera observes fluorescence from the beam at the laser cooling section. Typical measured horizontal beam size is 0.5mm (1 σ). In some condition, an increase of fluorescence strength is observed, which indicates the beam concentration to the center, where the beam and the laser can interact. PAT is utilized for measurement of a longitudinal beam velocity profile. By application of electric potential to the PAT, the beam velocity is slightly modified. Since only particles which have velocities in a certain region can interact with the laser, the time variation of the florescence during voltage sweep represents the longitudinal velocity profile of the beam. *H. Okamoto, Phys. Rev. E 50, 4982 (1994) |
||
| TH5PFP030 | Recent Approach to Crystalline Beam with Laser-Cooling at Ion Storage Ring, S-LSR | 3260 |
|
||
|
Funding: The present work was supported by Advanced Compact Accelerator Development program by MEXT of Japanese Government. Support from Global COE, The Next Generation of Physics, is also greatly appreciated. Creation of 3-dimensional crystalline beam by application of laser-cooling for a Mg ion beam with kinetic energy of 40 keV is a major research subject of the ion storage ring, S-LSR, at ICR, Kyoto University*. Based on the success of longitudinal laser cooling in 2007**, an approach to extend the effect of laser cooling to the transverse degree of freedom has been performed. An indication of heat transfer from the horizontal to longitudinal direction has been obtained by synchro-betatron coupling. By application of bunched beam laser cooling at the operation point around (2.07, 1.10), the momentum spread of the cooled ion beam has been observed to have a peak at a synchrotron tune around 0.07 and simultaneously transverse beam size seems to be reduced in this region. An increase of beam brightness in the horizontal profile has also been observed by measuring spontaneous emission of absorbed laser light. In the present paper, strategy to reach the final 3-dimensional crystalline state by application of 3-dimensional laser cooling by careful adjustment of coupling among 3 degrees of freedom is to be presented based upon the recent experimental results. *A. Noda, M. Ikegami, T. Shirai, New Journal of Physics, 8, 288-307(2006). |
||
| TH5PFP031 | Laser Cooling Experiment with Resonant Coupling at S-LSR | 3263 |
|
||
|
Funding: Work supported by Advanced Accelerator Development Project of MEXT, the Global COE program "The Next Generation of Physics, Spun from Universality and Emergence" and the Grant-in-Aid for JSPS Fellows. Laser cooling experiments have been carried out at Small Laser-equipped Storage Ring(S-LSR). In order to achieve transverse cooling, a resonant coupling method* is applied. In this method, the transverse temperature is cooled indirectly by synchro-betatron coupling, through an RF electric field at a straight section with a finite dispersion of 1.0 m. In this experiment, a Mg+ beam is cooled by a co-propagating laser with a wavelength of 280 nm under various values of tunes and several diffenence resonant conditions of a synchrotron and betatron tune. The momentum spread are measured by observing laser-induced fluorescence light by using a post acceleration tube. The transverse beam profiles are measured with a CCD camera. When the synchrotron tune and the horizontal betatron tune are 0.065 and 2.064, respectively, an enhancement of momentum spread is observed. In this resonant condition the momentum spread is increased from 1.5x10-4 to 3.0x10-3 at 3x107 stored particles. The effect of resonant coupling for transverse beam sizes is now under investigation. The tune dependence and time variation of the beam sizes by laser cooling is also a subject in the present experiments. *H. Okamoto, Phys. Rev. E 50, 4982 (1994) |
||
| FR5REP041 | Cryogenic Ion Beam Storage | 4860 |
|
||
|
Funding: This work is supported by the Max Planck Society. An electrostatic Cryogenic Storage Ring (CSR) is currently being built in Heidelberg, Germany. The current status and final design of this ring, with a focus on the precision chamber suspension, optimized 2K chamber cooling, and the cryogenic pumping down to extremely low pressures will be presented. This ring will allow long storage times of ion beams with energies in the range of keV per charge for highly charged ions and polyatomic molecules. Combined with vacuum chamber temperatures approaching 2K, infrared-active molecular ions will be radiatively cooled to their rotational ground states. Many aspects of this concept were experimentally tested with a cryogenic trap for fast ion beams (CTF), which has already demonstrated the storage of fast ion beams in a large cryogenic device. An upcoming test will investigate the effect of pre-baking the cryogenic vacuum chambers to 600K on the cryogenic vacuum and the ion beam storage. |