• 대한방사선기술학회지:방사선기술과학
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• 제43권5호
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• pp.389-395
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• 2020

The evaluation of radioactivated components of heavy-ion accelerator facilities affects the safety of radiation management and the exposure dose for workers. and this is an important issue when predicting the disposal cost of waste during maintenance and dismantling of accelerator facilities. In this study, the FLUKA code was used to simulate the proton treatment device nozzle and classify the radio-nuclides and total radioactivity generated by each component over a short period of time. The source term was evaluated using NIST reference beam data, and the neutron flux generated for each component was calculated using the evaluated beam data. Radioactive isotopes caused by generated neutrons were compared and evaluated using nuclide information from the International Radiation Protection Association and the Korea Radioisotope association. Most of the nuclides produced form of beta rays and electron capture, and short-lived nuclides dominated. However, In the case of ⁵⁴Mn, which is a radioactive product of iron, the effect of gamma rays should be considered. In the case of tritium generated from a material with a low atomic number, it is considered that handling care should be taken due to its long half-life.

• 대한핵의학회지
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• 제39권1호
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• pp.1-8
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• 2005

상용 PET사이클로트론의 기술적인 변화는 PET의 수요와 밀접한 관계가 있다. PET활용이 일반화 되어 미국을 중심으로 PET의 수요가 급증하게 됨에 따라 사이클로트론의 수요도 증가 하였다. 기존의 사이클로트론은 크기와 무게로 병원에 설치에 공간과 전원 공급 등 여러 문제가 있어 각 사이클로트론 제작사들은 새로운 모델을 출시하게 되었다. 새로운 모델의 특징은 다음과 같다. 첫째 기존의 모델이 양성자와 중양자 등의 2가지 이온을 인출 하였으나 시스템의 복잡성 등의 문제와 양성자로 O-15 생산이 가능하여 양성자 빔만을 인출 하거나 중양자는 선택 사양으로 전환 하였다. 둘째 기존 모델의 경우 양성자의 빔 에너지는 약 16 MeV 이상 가속 시킬 수 있으나 신 모델은 13 MeV 이내로 대폭 낮추어 PET 용 Rl생산에 최적화하였다. 셋째 전자석, RF 장치등의 최적화를 이룩하여 전력소모를 대폭 개선하였으며 외양도 대폭 작아져 무게를 20톤 이내로 대폭 낮추었다. 넷째 새로운 모델 사이클로트론들은 자체 차폐기능이 일반화 되었으나 IBA제품이나 삼영유니텍 제품은 사용자의 견지에 따라 선택 사양이 가능하다.

• Nuclear Engineering and Technology
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• 제53권4호
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• pp.1378-1389
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• 2021

TRIUMF, Canada's particle accelerator centre, is constructing a new high-power ISOL (Isotope Separation On-Line) facility called ARIEL (Advanced Rare IsotopE Laboratory). Thick porous targets will be bombarded with up to 48 kW of 480 MeV protons from TRIUMF's cyclotron, or up to 100 kW of 30 MeV electrons from a new e-linac, to produce short-lived radioisotopes for a variety of applications, including nuclear astrophysics, fundamental nuclear structure and nuclear medicine. For efficient release of radioisotopes, the targets are heated to temperatures approaching 2000 ℃, and are exposed to GSv/h level radiation fields resulting from intended fissions and spallations. Due to these conditions, the operational life for each target is only about five weeks, calling for frequent remote target exchanges to limit downtime. A few days after irradiation, the targets have a residual radiation field producing a dose rate on the order of 10 Sv/h at 1 m, requiring several years of decay prior to shipment to a national disposal facility. TRIUMF is installing new remote handling infrastructure dedicated to ARIEL, including hot cells and a remote handling crane. The system design applies learnings from multiple existing facilities, including CERN-ISOLDE, GANIL-SPIRAL II as well as TRIUMF's ISAC (Isotope Separator and ACcelerator).