利用带 Schroeder 扩散器结构的壁波纹抑制圆柱形陀螺仪光束隧道中的寄生模态

IF 1.3 4区物理与天体物理 Q3 PHYSICS, FLUIDS & PLASMAS

IEEE Transactions on Plasma Science Pub Date : 2024-07-31 DOI:10.1109/TPS.2024.3412373

Heinrich P. Laqua;Sergiy Ponomarenko

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引用次数: 0

摘要

借助与所谓施罗德相位光栅相对应的特殊边缘结构，可以对圆柱形波导中的电磁场进行扰动，从而使大径向区域的平均电场强度降低到回旋共振频率范围内所有特征模式的平均值。这种扰动打破了模式的对称性，抑制了局部最大值的大小，就像在消声室中一样。通过使用 Ansys HFSS 软件进行计算机模拟，证明了在光滑壁面圆柱形波导中引入 Schroeder 结构对电磁场分布的破坏。将所提出的结构与应用于大功率陀螺仪波束隧道的光滑表面和对称波纹表面进行了比较。在陀螺仪的电子束压缩区域应用 Schroeder 结构可以增加腔前寄生振荡的启动电流。因此，增加工作束流和提高陀螺仪输出功率的可能性非常大。

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Suppression of Parasitic Modes in a Cylindrical Gyrotron Beam Tunnel by a Wall Corrugation With Schroeder Diffuser Structures

With the help of special edge structures, which correspond to the so-called Schroeder phase gratings, the electromagnetic field in a cylindrical waveguide can be perturbed in such a way that in large radial regions, an average electric field strength is reduced to a mean value for all eigenmodes existing in the frequency range of a cyclotron resonance. The perturbations break symmetry of the modes and suppress the magnitude of local maxima like in an anechoic room. The destruction of electromagnetic field distributions in a smooth-walled cylindrical waveguide due to the introduction of a Schroeder structure on a wall has been demonstrated with the help of computer simulations using the Ansys HFSS software. The proposed structure was compared with both smooth and symmetrically corrugated surfaces, which are applied in the beam tunnels of high-power gyrotrons. The application of the Schroeder structures in electron beam compression region of a gyrotron allows to increase the starting currents for parasitic before-cavity oscillations. Consequently, there is an attractive possibility to increase the operating beam current and enhance the output power of gyrotrons.

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来源期刊

IEEE Transactions on Plasma Science 物理-物理：流体与等离子体

CiteScore

3.00

自引率

20.00%

发文量

538

审稿时长

3.8 months

期刊介绍： The scope covers all aspects of the theory and application of plasma science. It includes the following areas: magnetohydrodynamics; thermionics and plasma diodes; basic plasma phenomena; gaseous electronics; microwave/plasma interaction; electron, ion, and plasma sources; space plasmas; intense electron and ion beams; laser-plasma interactions; plasma diagnostics; plasma chemistry and processing; solid-state plasmas; plasma heating; plasma for controlled fusion research; high energy density plasmas; industrial/commercial applications of plasma physics; plasma waves and instabilities; and high power microwave and submillimeter wave generation.