Your search keyword '"Tang, Jing-Yu"' showing total 7 results

1. Courant-Snyder invariant density screening method for emittance analysis

Author

Sun Ji-Lei, Jing Han-Tao, and Tang Jing-Yu

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, Classical mechanics, Invariant density, Hadron, Screening method, Physics::Accelerator Physics, Astronomy and Astrophysics, Thermal emittance, Instrumentation, Charged particle, Beam (structure)

Abstract

Emittance is an important characteristic of describing charged particle beams. In hadron accelerators, we often meet irregular beam distributions that are not appropriately described by a single rms emittance or 95% emittance or total emittance. In this paper it is pointed out that in many cases a b...

Published

2011

2. Irradiation methods and nozzle design for the advanced proton therapy facility

Author

Li Gang, Fang Shou-Xian, Shu Hang, Qiu Jing, Tang Jing-Yu, Fu Shi-Nian, Jiao Yi, Liu Li, Liu De-Kang, Chen Yuan, and Guan Xialing

Subjects

Physics, Nuclear and High Energy Physics, business.industry, Nuclear engineering, Physics::Medical Physics, Nozzle, Treatment method, Astronomy and Astrophysics, Synchrotron, Fixed Beam, law.invention, Optics, law, Physics::Accelerator Physics, Irradiation, Pencil-beam scanning, business, Instrumentation, Proton therapy, Beam (structure)

Abstract

A conception design of the Advanced Proton Therapy Facility (APTF) has been carried out. The system intentionally employs a slow-cycling synchrotron with a maximum energy of 250 MeV, two rotating gantries and two fixed beam nozzles for the treatment. In this paper, we try to compare the strength and weaknesses between the two treatment methods: the beam spreading and the pencil beam scanning. The application of the pencil beam scanning method and the double-scattering method together with the related nozzle design at APTF is also given. The simulation results of employing the double-scattering method have been given during the preliminary design.

Published

2010

3. Physical design of scanning gantry for proton therapy facility

Author

Tang Jing-Yu, Shu Hang, Chen Yuan, Qiu Jing, Wei Jie, Satogata Todd, Jiao Yi, Guan Xialing, and Fang Shou-Xian

Subjects

Physics, Nuclear and High Energy Physics, medicine.medical_specialty, business.industry, Isocenter, Astronomy and Astrophysics, Injector, Synchrotron, Linear particle accelerator, law.invention, Optics, law, medicine, Medical physics, Sensitivity (control systems), Physical design, business, Instrumentation, Proton therapy, Beam (structure)

Abstract

A proton therapy facility based on a linac injector and a slow cycling synchrotron is proposed. To achieve effective treatment of cancer, a scanning gantry is required. The flexible transmission of beam and high beam position accuracy are the most basic requirements for a gantry. The designed gantry optics and scanning system are presented. Great efforts are put into studying the sensitivity of the beam position in the isocenter to the element misalignments. It shows that quadrupole shift makes the largest contribution and special attention should be paid to it.

Published

2010

4. ATPF – a dedicated proton therapy facility

Author

Ouyang Hua-Fu, Shu Hang, Deng Chang-Dong, Dong Hai-Yi, Qiu Jing, Jiao Yi, Yang Mei, Fu Shi-Nian, Chen Yuan, Guan Xialing, Wei Jie, Sun Hong, Shi Cai-Tu, Tang Jing-Yu, Zhang Jing, and Fang Shou-Xian

Subjects

Physics, Nuclear and High Energy Physics, business.industry, Astronomy and Astrophysics, Solenoid, Particle accelerator, Injector, Synchrotron, Linear particle accelerator, law.invention, Nuclear magnetic resonance, Optics, law, Physics::Accelerator Physics, Thermal emittance, business, Instrumentation, Proton therapy, Beam (structure)

Abstract

A proton therapy facility based on a linac injector and a slow-cycling synchrotron is proposed. To obtain good treatments for different cancer types, both the spot scanning method and the double-scattering method are adopted in the facility, whereas the nozzles include both gantry and fixed beam types. The proton accelerator chain includes a synchrotron of 250 MeV in maximum energy, an injector of 7 MeV consisting of an RFQ and a DTL linac, with a repetition rate of 0.5 Hz. The slow extraction using the third-order resonance and together with the RFKO method is considered to be a good method to obtain a stable and more-or-less homogenous beam spill. To benefit the spot scanning method, the extraction energy can be as many as about 200 between 60 MeV and 230 MeV. A new method - the emittance balancing technique of using a solenoid or a quadrupole rotator is proposed to solve the problem of unequal emittance in the two transverse planes with a beam slowly extracted from a synchrotron. The facility has been designed to keep the potential to be upgraded to include the carbon therapy in the future.

Published

2010

5. Matching by solenoids in space charge dominated LEBTs

Author

Tang Jing-Yu, Ouyang Hua-Fu, and LI Jin-Hai

Subjects

Coupling, Physics, Nuclear and High Energy Physics, Field (physics), Astronomy and Astrophysics, Charge (physics), Betatron, Space charge, Computational physics, Transverse plane, Quantum mechanics, Physics::Accelerator Physics, Thermal emittance, Instrumentation, Beam (structure)

Abstract

The betatron matching of a rotationally asymmetric beam in space charge dominated low-energy beam transports (LEBTs) where solenoids are used for the transverse matching has been studied. For better understanding, the coupling elements of a beam matrix are interpreted in special forms that are products of a term defined by the Larmor rotation angle and another by the difference between the beam matrix elements in the two transverse planes. The coupling form originally derived from the rotationally symmetric field in solenoids still holds when taking into account the rotationally asymmetric space charge forces that are due to the unequal emittance in the two transverse planes. It is shown in this paper that when an LEBT mainly comprising solenoids transports a beam having unequal emittance in the two transverse planes and the linear space charge force is taken into account, the initial Twiss parameters can be modified to obtain the minimum and equal emittance at the LEBT exit. The TRACE3D calculations also prove the principle. However, when quadrupoles that are also rotationally asymmetric are involved in between solenoids, the coupling between the two transverse planes becomes more complicated and the emittance increase is usually unavoidable. A matching example using the CSNS (China Spallation Neutron Source) LEBT conditions is also presented.

Published

2009

6. RF trapping and acceleration in CSNS/RCS

Author

Qin Qing, Wei Tao, Tang Jing-Yu, and Fu Shi-Nian

Subjects

Physics, Nuclear and High Energy Physics, Momentum (technical analysis), business.industry, Aperture, Astronomy and Astrophysics, Acceleration, Transverse plane, Optics, Nuclear magnetic resonance, Magnet, Physics::Accelerator Physics, Waveform, business, Instrumentation, Beam (structure), Voltage

Abstract

In this paper, two injection scenarios with different chopping rate are discussed. The waveforms of the RF voltage are studied and optimized, respectively. Some suggestions are made, concerning chopping and momentum painting of the injected beam. Furthermore, the momentum spread and transverse tune shift are calculated so that the beam aperture and the beam loss can be estimated. Finally, the beam loss with magnet field error is analyzed.

Published

2008

7. Introduction to the overall physics design of CSNS accelerators

Author

Liu Wei-Bin, Fang Shou-Xian, Wang Sheng, Fu Shi-Nian, Ouyang Hua-Fu, Qin Qing, Wei Jie, and Tang Jing-Yu

Subjects

Physics, Nuclear and High Energy Physics, Nuclear engineering, Astronomy and Astrophysics, Synchrotron, Linear particle accelerator, law.invention, Nuclear physics, Low energy, law, Rapid cycling, Physics::Accelerator Physics, Instrumentation, Beam (structure), Spallation Neutron Source

Abstract

The China Spallation Neutron Source (CSNS) is an accelerator-based facility. The accelerator of CSNS consists of a low energy linac, a Rapid Cycling Synchrotron (RCS) and two beam transport lines. The overall physics design of CSNS accelerator is described, including the design principle, the choice of the main parameters and design of each part of accelerators. The key problems of the physics design, such as beam loss and control, are also discussed. The interface between the different parts of accelerator, as well as between accelerator and target, are introduced.

Published

2009