共查询到17条相似文献,搜索用时 265 毫秒
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电磁波与非磁化等离子体的相互作用 总被引:22,自引:4,他引:22
研究了频率为0.5-10HGz的电磁波在非磁化等离子体中的传播。在厚度为10cm的、密度n=10^10或10^11cm^-3的均匀和密度分布n=n0exp[2(z/d-1)]非均匀的等离子体中,计算了等离子体中的电子与中性气体的碰撞频率为0.1-10GHz间的电磁波的反射功率,吸收功率 透射功率的变化。结果表明当等离子体密度比较大(n=10^11cm^-3)、电子与中性气体的碰撞频率比较大时,无论是均匀还是非均匀等离子体对电磁波能量的吸收都比较大,最大可达90%。 相似文献
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研究了平面电磁波在磁化、稳定、二维、非均匀等离子体中的传播特性;采用等效输入阻抗方法计算非均匀磁化等离子体层对不同模式入射电磁波的功率吸收情况。结果表明,电子数密度、碰撞频率和外磁场大小是等离子体对电磁波功率吸收的主要影响因素。采用等效介电常数的方法模拟等离子体特性,代入有限元软件进行平面电磁波入射等离子体仿真,得到了非寻常波与右旋极化波的吸收特性。根据数值计算和全波仿真结果可知,当等离子体密度为1017 m-3、碰撞频率2.5 GHz、外加磁场的磁感应强度为0.15 T时,磁化等离子体对电磁波有强烈的吸收特性。 相似文献
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利用荧光灯等离子体管覆盖金属腔体内壁,测量了筒状等离子体覆盖的金属腔体对电磁波的回波衰减。测试结果表明:金属圆筒内壁的等离子体能够有效吸收0.80~1.75 GHz波段的入射波,入射电磁波的回波衰减值为5~25 dB;当入射电磁波频率接近1.75 GHz时,回波衰减最为强烈,在入射角度为10°时,吸收峰值可达26.71 dB,因此选择合适的电磁波入射角度,能够使等离子体对微波的吸收达到峰值。理论分析了影响等离子体对电磁波衰减的主要因素。结果表明:等离子体可有效缩减腔体结构的雷达散射截面面积,因此在进气道等腔体结构的隐身方面具有一定的应用前景。 相似文献
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等离子体对高功率微波的防护 总被引:1,自引:0,他引:1
提出了用等离子体防护高功率微波破坏电子设备的方法。建立了“介质层-等离子体层-介质层-等离子体层”的反射/吸收模型,其中两层均匀非磁化等离子体厚度各为50mm,等离子体频率为30GHz,等离子碰撞频率为70GHz。计算了微波的透射功率、防护结构的最小防护距离。计算结果表明:对功率10GW、脉冲宽度100ns、天线100m2 (效率50%)的微波源产生的微波,频率小于30GHz时,将被防护装置反射;频率为31~80GHz时,防护结构的最小防护距离约为5km。 相似文献
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针对等离子体隐身技术在航空航天领域的良好应用前景, 开展垂直入射到具有金属衬底的非磁化等离子体中电磁波衰减特性的理论与实验研究. 利用WKB方法对电磁波衰减随等离子体参数的变化规律进行了理论分析. 利用射频电感耦合放电方式产生稳定的大面积等离子体层, 搭建了等离子体反射率弓形测试系统, 进行了电磁波在非磁化等离子体中衰减效应的实验研究. 利用微波相位法和光谱诊断法, 得到不同放电功率下的等离子体电子密度, 其范围为8.17×109–7.61× 1010 cm-3. 本实验获得的等离子体可以使2.7 GHz 和10.1 GHz电磁波分别得到一定的衰减, 且电磁波衰减的理论与实验结果符合较好. 结果表明, 提高等离子体电子密度和覆盖均匀性有利于增强等离子体对电磁波的衰减效果. 相似文献
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利用荧光灯排列形成非均匀等离子体层(面积约60cm×52cm,消耗功率约400W),研究了其对1~8GHzE波(电矢量方向平行于灯轴方向的入射波)的反射和透射的影响。结果表明,该等离子体对1~4GHz的E波具有强吸收和弱反射的特性,单程衰减最高可达8dB。利用2维分段线性电流密度递归卷积时域有限差分计算式,模拟了E波传播及其在非均匀等离子体内推进的瞬态过程,计算了等离子体对电磁波的反射和透射衰减,并与实验结果拟合,得到等离子体电子数密度峰值约9.72×1016m-3,电子与中性粒子碰撞频率约4GHz。 相似文献
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射频电感耦合等离子体(ICP)放电方式能够在较宽的压强范围内产生大面积、密度高的等离子体,在对电磁波衰减应用中具有较大优势。通过研究ICP等离子体与电磁波相互作用的过程,改进闭式等离子体模型,建立电磁波在非均匀等离子体中传播的分层计算模型,对实测诊断分布情形下等离子体与电磁波的相互作用进行研究,得到不同功率条件下电磁波衰减的变化情况;提出射频电感耦合闭式等离子体用于电磁波衰减的方法并实验验证,基于等离子体覆盖金属平板的测量模型,在实验室内搭建了以金属板为衬底的弓形微波反射测试系统,研究了闭式等离子体对4~8 GHz频段范围内微波反射的作用特性,以及不同射频功率对微波反射的影响规律,并将实验测量与计算结果进行对比分析。实验表明,通过功率调节,电感耦合闭式等离子体对5.92~6.8 GHz频带电磁波具有明显的衰减作用。 相似文献
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针对飞机进气道等离子体隐身问题,建立了三维筒形进气道模型,采用有限元求解波动方程,计算了腔体内壁覆盖均匀等离子体时的雷达散射截面。研究表明:腔体内覆盖等离子体时可以有效吸收入射电磁波能量;吸收随电磁波频率增加而减弱,但由于腔体结构作用,会存在几个吸收峰;吸收随电子数密度增加而增强,但电子数密度过高时,吸收效果会变差;最佳碰撞频率虽然与电磁波频率和电子数密度有关,但其值可约为9GHz;吸收随等离子体厚度增加而变大,但在较大电子数密度时,由于电磁波在等离子体与空气交界面处反射导致厚度增加,从而使得吸收变小;选取合适的入射角度和等离子体数密度可以在1~3GHz频段实现明显的隐身效果。 相似文献
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Tang D.L. Sun A.P. Qiu X.M. Chu P.K. 《IEEE transactions on plasma science. IEEE Nuclear and Plasma Sciences Society》2003,31(3):405-410
The absorption, reflection, and transmission of electromagnetic waves by a nonuniform plasma slab immersed in an ambient uniform magnetic field of various strengths are studied in this paper. The effects of the plasma parameters and magnetic field strength on the absorbed, reflected, and transmitted power are discussed. The magnetized nonuniform plasma slab is modeled by a series of magnetized uniform plasma subslabs. The calculation results show that the effects of the magnetic field strength and density gradient on the absorbed power, as well as the frequency band of resonant absorption, are significant. A complete analysis utilizing the scattering matrix method is also used to compare the above calculation results which neglect multiple reflections between subslab interfaces. Broadband absorption of electromagnetic waves can be achieved by changing the magnetic field strength and plasma density. More than 90% of the electromagnetic wave power can be absorbed in a magnetized nonuniform plasma slab with width of 12 cm and the absorption bandwidth can range from 1 to 20 GHz with different plasma parameters and external magnetic field strengths. 相似文献
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In this paper, a model for calculating the reflection and absorption powers of electromagnetic wave (EM wave) in nonuniform magnetized plasma slab is given out based on layer propagation theory. The effects of various plasma parameters and different values of magnetic field intensity on the reflected and absorbed powers are discussed. The results illustrate that the thickness of plasma seldom affects the reflection of radar wave, but it can broaden or reduce the absorption width. Meanwhile, the background magnetic field intensity has an influence upon the results, and it could change the resonance spectrum of magnetized plasma. We also find out that, with appropriate plasma density, collision frequency and magnetic field intensity, more than 90% of radar wave power can be absorbed and the resonant absorption band is about 2 GHz. 相似文献
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The stability of high‐frequency potential surface waves at a dense magnetized plasma – metal interface with respect to a low‐frequency plasma density modulation is studied in the point of view of the surface waves control. The discussion is addressed to the situation, when an external steady magnetic field is directed perpendicularly to the interface. The nonlinear interaction process of the high‐frequency surface wave, its satellites and the low‐frequency plasma density perturbation is investigated. It is shown that the low‐frequency plasma density perturbation can be represented as a superposition of forced waves of surface and volume types and can lead to an additional attenuation of the surface waves. This attenuation arises when the surface wave amplitude exceeds the threshold value. (© 2003 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim) 相似文献
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采用空间透射波测量方法,实验研究透波密闭石英玻璃容器内等离子体喷流对垂直和水平极化电磁波的衰减,在有和无外加磁场条件下分析实验参数对等离子吸波效应的影响,分析等离子体的吸波机理.实验结果表明在非磁和本实验条件下,平面电磁波在等离子体中的衰减机理为碰撞吸收;在有磁和本实验条件下,平面电磁波在磁等离子体中的衰减机理同样为碰撞吸收,但是外加磁场的存在有限地改善了等离子体的吸波效应.为了使磁等离子体最有效地吸收电磁波,应该提高磁场感应强度,把高频混杂频率提高到测试微波频率范围内,或降低微波测试频率至本实验中的高混
关键词:
等离子体相互作用
电磁波
电磁波在等离子体中的传输 相似文献
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Plasma characteristics and broadband electromagnetic wave absorption in argon and helium capacitively coupled plasma 下载免费PDF全文
《中国物理 B》2021,30(9):95203-095203
A one-dimensional self-consistent calculation model of capacitively coupled plasma(CCP) discharge and electromagnetic wave propagation is developed to solve the plasma characteristics and electromagnetic wave transmission attenuation.Numerical simulation results show that the peak electron number density of argon is about 12 times higher than that of helium, and that the electron number density increases with the augment of pressure, radio frequency(RF) power, and RF frequency. However, the electron number density first increases and then decreases as the discharge gap increases. The transmission attenuation of electromagnetic wave in argon discharge plasma is 8.5-d B higher than that of helium. At the same time, the transmission attenuation increases with the augment of the RF power and RF frequency, but it does not increase or decrease monotonically with the increase of gas pressure and discharge gap. The electromagnetic wave absorption frequency band of the argon discharge plasma under the optimal parameters in this paper can reach the Ku band. It is concluded that the argon CCP discharge under the optimal discharge parameters has great potential applications in plasma stealth. 相似文献