强激光与粒子束
彊激光與粒子束
강격광여입자속
HIGH POWER LASER AND PARTICLEBEAMS
2010年
1期
109-113
,共5页
葛行军%杜广星%朱俊%钟辉煌%钱宝良
葛行軍%杜廣星%硃俊%鐘輝煌%錢寶良
갈행군%두엄성%주준%종휘황%전보량
导引磁场%相对论返波振荡器%励磁电源%高功率微波源
導引磁場%相對論返波振盪器%勵磁電源%高功率微波源
도인자장%상대론반파진탕기%려자전원%고공솔미파원
guiding magnetic field%relativistic backward wave oscillator%magnetic field stimulating power%high power microwave sources
设计了一个用于为L波段同轴相对论返波振荡器提供导引磁场的双线绕制、分段磁场线圈系统.根据粒子模拟中对磁场的要求和实验室已有的条件来确定磁场的各参数,通过数学软件Mathcad和全电磁粒子模拟程序Karat对设计出的轴向磁场位形进行验证.采用基于Hall效应的Tesla计对加工好的磁场线圈产生轴向磁场空间分布进行了测量,同时利用电子束轰击尼龙靶来考察电子束被导引的效果.利用绕制好的磁场线圈开展了初步实验研究,在二极管电压655 kV,电子束流为10.4 kA,导引磁场0.7 T的条件下,输出微波峰值功率约为864 MW,微波波形半高宽为23 ns,功率转换效率约为12.7%,频率1.61 GHz.
設計瞭一箇用于為L波段同軸相對論返波振盪器提供導引磁場的雙線繞製、分段磁場線圈繫統.根據粒子模擬中對磁場的要求和實驗室已有的條件來確定磁場的各參數,通過數學軟件Mathcad和全電磁粒子模擬程序Karat對設計齣的軸嚮磁場位形進行驗證.採用基于Hall效應的Tesla計對加工好的磁場線圈產生軸嚮磁場空間分佈進行瞭測量,同時利用電子束轟擊尼龍靶來攷察電子束被導引的效果.利用繞製好的磁場線圈開展瞭初步實驗研究,在二極管電壓655 kV,電子束流為10.4 kA,導引磁場0.7 T的條件下,輸齣微波峰值功率約為864 MW,微波波形半高寬為23 ns,功率轉換效率約為12.7%,頻率1.61 GHz.
설계료일개용우위L파단동축상대론반파진탕기제공도인자장적쌍선요제、분단자장선권계통.근거입자모의중대자장적요구화실험실이유적조건래학정자장적각삼수,통과수학연건Mathcad화전전자입자모의정서Karat대설계출적축향자장위형진행험증.채용기우Hall효응적Tesla계대가공호적자장선권산생축향자장공간분포진행료측량,동시이용전자속굉격니룡파래고찰전자속피도인적효과.이용요제호적자장선권개전료초보실험연구,재이겁관전압655 kV,전자속류위10.4 kA,도인자장0.7 T적조건하,수출미파봉치공솔약위864 MW,미파파형반고관위23 ns,공솔전환효솔약위12.7%,빈솔1.61 GHz.
A solenoid using the double winding technique has been designed to drive a coaxial relativistic backward wave oscillator(RBWO). First, the solenoid parameters were chosen by the particle simulation and practical applications. In addition, the magnetic field distribution was validated by numerical calculations with the Mathcad code and the particle-in-cell(PIC) Karat code. Then the profile of the axial magnetic field distribution was measured by a Tesla-meter based on the Hall effect, and the guiding effect of the field was examined by electrons bombarding a nylon target. Based on the above discussion, the primary experiment with the solenoid was carried out. The measured microwave frequency is 1.61 GHz, with a peak power level of above 864 MW, when the diode voltage is 655 kV and the current is 10.4 kA. The pulse duration (full-width at half-maximum) of the radiated microwave is 23 ns.
