Your search keyword '"Simakov, A. I."' showing total 5 results

1. Experimental Study of Wakefields in an X-band Photonic Band Gap Accelerating Structure.

Author

Simakov, Evgenya I., Arsenyev, Sergey A., Buechler, Cynthia E., Edwards, Randall, and Romero, William

Subjects

*ENERGY bands, *PHOTONIC band gap structures, *PLASMA accelerators, *TRAVELING waves (Physics), *ELECTROMAGNETIC coupling

Abstract

We designed an experiment to conduct a detailed investigation of the higher order mode spectrum in a roomtemperature traveling-wave photonic band gap (PBG) accelerating structure at 11.7 GHz. It has been long recognized that PBG structures have great potential in reducing long-range wakefields in accelerators. The first ever demonstration of acceleration in room-temperature PBG structures was conducted at MIT in 2005. Since then, the importance of that device has been recognized by many research institutions. However, the full experimental characterization of the wakefield spectrum in a beam test has not been performed to date. The Argonne Wakefield Accelerator (AWA) test facility at the Argonne National Laboratory represents a perfect site where this evaluation could be conducted with a single high charge electron bunch and with a train of bunches. The PBG structure was built and consists of sixteen 2π/3 traveling-wave cells, including two coupler cells. In this paper we will describe fabrication and tuning of the PBG cells, and the results of the final cold-test of the traveling-wave accelerating structure. Next we will discuss the plan for the wakefield experiment. [ABSTRACT FROM AUTHOR]

Published

2016

2. The design of a five-cell superconducting RF module with a PBG coupler cell.

Author

Arsenyev, Sergey A. and Simakov, Evgenya I.

Subjects

*SUPERCONDUCTORS, *RADIO frequency modulation, *PHOTONIC band gap structures, *ELECTRON accelerators, *MAGNETIC fields, *PARTICLE acceleration

Abstract

We discuss the problem of incorporating a Photonic Band Gap (PBG) cell into a superconducting accelerating module of 5 cells designed for the operational frequency of 2.1 GHz. The reason for using a PBG cell is to provide a good accelerating mode confinement and good Higher Order Mode (HOM) suppression. PBG cell can potentially be used for placing HOM and fundamental mode couplers. However, because of the naturally higher ratio of the peak magnetic field to the accelerating field in the PBG cell, it should be designed to operate at a lower accelerating gradient than the other cells of the module. This ensures that the probability of quench in the PBG cell would be no higher than in other elliptical cells of the structure. [ABSTRACT FROM AUTHOR]

Published

2012

3. Raising gradient limitations in 2.1GHz superconducting photonic band gap accelerator cavities.

Author

Simakov, Evgenya I., Arsenyev, Sergey A., Haynes, W. Brian, Shchegolkov, Dmitry Yu., Suvorova, Natalya A., Tsuyoshi Tajima, Boulware, Chase H., and Grimm, Terry L.

Subjects

*SUPERCONDUCTORS, *PHOTONIC band gap structures, *RADIO frequency, *MICROFABRICATION, *LIQUID helium

Abstract

We report results from recent 2.1GHz superconducting radio frequency (SRF) photonic band gap (PBG) resonator experiments at Los Alamos. Two 2.1GHz PBG cells with elliptical rods were fabricated and tested at high power in a liquid helium bath at the temperatures of 4K and below 2K. The described SRF PBG cells were designed with a particular emphasis on changing the shape of the PBG rods to reduce peak surface magnetic fields and at the same time to preserve its effectiveness at damping higher-order-modes. The superconducting PBG cavities have great potential for damping long-range wakefields in SRF accelerator structures without affecting the fundamental accelerating mode. The cells performed in accordance with simulation's predictions and the maximum achieved accelerating gradient was 18.3 MV/m. This represents a 30% increase over gradients previously demonstrated in superconducting PBG cavities with round rods. [ABSTRACT FROM AUTHOR]

Published

2014

4. First High Power Test Results for 2.1 GHz Superconducting Photonic Band Gap Accelerator Cavities.

Author

Simakov, Evgenya I., Haynes, W. Brian, Madrid, Michael A., Romero, Frank P., Tajima, Tsuyoshi, and Tuzel, Walter M.

Subjects

*SUPERCONDUCTIVITY, *PHOTONIC band gap structures, *PARTICLE accelerators, *PLASMA instabilities, *LUMINESCENCE, *FREE electron lasers

Abstract

We report the results of the recent high power testing of superconducting radio frequency photonic band gap (PBG) accelerator cells. Tests of the two single-cell 2.1 GHz cavities were performed at both 4 and 2 K. An accelerating gradient of 15 MV/m and an unloaded quality factor Q0 of 4 .109.were achieved. It has been long realized that PBG structures have great potential in reducing long-range wakefields in accelerators. A PBG structure confines the fundamental TM0i-like accelerating mode, but does not support higher order modes. Employing PBG cavities to filter out higher order modes in superconducting particle accelerators will allow suppression of dangerous beam instabilities caused by wakefields and thus operation at higher frequencies and significantly higher beam luminosities. This may lead towards a completely new generation of colliders for high energy physics and energy recovery linacs for the free-electron lasers. [ABSTRACT FROM AUTHOR]

Published

2012

5. Observation of Wakefield Suppression in a Photonic-Band-Gap Accelerator Structure.

Author

Simakov, Evgenya I., Arsenyev, Sergey A., Buechler, Cynthia E., Edwards, Randall L., Romero, William P., Conde, Manoel, Gwanghui Ha, Power, John G., Wisniewski, Eric E., and Chunguang Jing

Subjects

*PHOTONIC band gap structures, *PARTICLE accelerators, *TRAVELING waves (Physics)

Abstract

We report experimental observation of higher order mode (HOM) wakefield suppression in a room-temperature traveling-wave photonic-band-gap (PBG) accelerating structure at 11.700 GHz. It has been long recognized that PBG structures have the potential for reducing long-range wakefields in accelerators. The first ever demonstration of acceleration in a room-temperature PBG structure was conducted in 2005. Since then, the importance of PBG accelerator research has been recognized by many institutions. However, the full experimental characterization of the wakefield spectrum and demonstration of wakefield suppression when the accelerating structure is excited by an electron beam has not been performed to date. We conducted an experiment at the Argonne Wakefield Accelerator test facility and observed wakefields excited by a single high charge electron bunch when it passes through a PBG accelerator structure. Excellent HOM suppression properties of the PBG accelerator were demonstrated in the beam test. [ABSTRACT FROM AUTHOR]

Published

2016