辐射与发光 光辐射与辐射源

O432．1 2005042439 正电子面沟道辐射的非线性特征=Nonlinear properties for the planar channelling radiation of a positrons[刊,中]／韦洛霞(东莞理工学院．广东,东莞(523106)),李勇…／／发光学报．-2005,26(2)．-168-172 从Lindhard势出发,在小振辐近似下,将其展开到四次项;在经典力学的框架内,将粒子运动方程化为含立方项的二阶非线性微分方程。利用Jacobian椭圆函数和第一类全椭圆积分解析表示了系统的解和粒子运动的周期, 导出了正电子面沟道辐射的瞬时辐射强度、平均辐射强度和最大辐射频率,得到了与实验相符合的结果,指出了利用沟道辐射作为γ激光的可能性。参11(于晓光)     

掺杂超晶格量子阱的沟道效应与沟道辐射

分析了超晶格量子阱的沟道效应和沟道辐射,利用正弦平方势描述了掺杂超晶格量子阱沟道粒子的运动行为,并在经典力学框架内,把粒子的运动方程化为摆方程。用Jacobian椭圆函数和椭圆积分解析地给出了系统的解和粒子运动周期,导出了量子阱沟道辐射的辐射强度和辐射能量。结果表明,对于能量为100 MeV左右的电子,辐射能量可达keV量级（X能区）。指出了用量子阱沟道辐射作为X激光或γ激光的可能性。     

正弦平方势与正电子面沟道辐射的一般特征

引入正弦平方势，在经典力学框架内，将面沟道粒子的运动方程化为标准的摆方程，并用Jacobian椭圆函数和椭圆积分解析地给出系统的解和粒子运动周期，导出了正电子面沟道辐射的瞬时辐射强度、平均辐射强度和辐射谱特征.结果表明，沟道辐射频率己进入γ-能区，并指出了利用它作为短波长激光的可能性. 关键词： 沟道辐射 非线性 正弦平方势     

掺杂超晶格量子阱的沟道效应与沟道辐射

 分析了超晶格量子阱的沟道效应和沟道辐射,利用正弦平方势描述了掺杂超晶格量子阱沟道粒子的运动行为,并在经典力学框架内,把粒子的运动方程化为摆方程。用Jacobian椭圆函数和椭圆积分解析地给出了系统的解和粒子运动周期,导出了量子阱沟道辐射的辐射强度和辐射能量。结果表明,对于能量为100 MeV左右的电子,辐射能量可达keV量级（X能区）。指出了用量子阱沟道辐射作为X激光或γ激光的可能性。     

反比相关的双曲余弦平方势与电子的面沟道辐射

带电粒子在晶体沟道中的运动行为决定于粒子-晶体相互作用势.常用的粒子晶体相互作用势有Lindhard势、Moliere和正弦平方势.当超相对论电子沿着晶体的低晶面指数方向入射时,电子和晶体之间的相互作用势可用反比相关的双曲余弦平方势描写.在量子力学框架内,利用这一相互作用势成功地将系统的Schrodinger方程化为超几何方程,从而简化了系统本征值和本征态问题的计算和讨论.考虑到质量的相对论效应和频率的Doppler效应,导出了实验室坐标系中电子的能级分布和辐射谱分布.并以电子的Si(110)面沟道辐射为例,选定一组与入射粒子有关的参数和一组与晶体有关的参数,计算了能量为E=0.5GeV的电子在低位能级之间的跃迁,导出了电子面沟道辐射能量ΔE=49.1MeV,得到了与实验符合的结果.     

反比相关的双曲余弦平方势与相对论电子面沟道辐射的经典描述

在经典力学框架内,描述了带电粒子自发辐射谱分布与最大辐射频率;引入反比相关的双曲余弦平方势,讨论了超相对论电子的面沟道辐射,导出了电子能量E=5.0GeV时,一次谐波的最大辐射能量ε=57MeV,与其他工作比较基本一致.沟道辐射与自由电子激光十分类似,它的方向性极好,大都集中在粒子运动方向、角宽Δθ≈γ^-1/2范围内;且能量高、连续可调,偏振度也很好.指出了利用超晶格沟道辐射与超晶格的多层薄膜结构相互作用,可望把自发的沟道辐射改造为相干辐射,从而得到X激光或γ激光.     

正弦平方势与沟道辐射谱线的自然展宽

指出了非线性效应、多普勒效应、晶格热振动、电子多重散射和偶极效应等对沟道辐射谱线宽度的影响;强调了辐射反作用对谱线宽度的影响是不可避免的。比较了不同的粒子-晶体相互作用势,并从正弦平方势出发,在小振幅近似下讨论了沟道粒子的运动行为;用摄动法求解了系统的特征方程,计算了沟道辐射谱线的自然展宽和频率漂移。最后,以正电子的Si(110)面沟道辐射为例,计算了它的辐射频率。结果表明,对于能量为E=56MeV的正电子,沟道辐射能量E=ω=36.0keV。     

Lindhard势与弯晶摆动场辐射的动力学稳定性

在经典力学框架内和偶极近似下,引入Lindhard势,把粒子运动方程转化为具有硬弹簧特性的达芬(Duffing)方程,利用多尺度法分析了系统的主共振和超共振;讨论了粒子在共振线附近运动的非线性行为;导出了系统的临界参数ac及满足系统稳定的条件。由于系统的临界条件与它的物理参数有关,只需这些参数适当,系统的不稳定性就可以原则上避免,从而保证系统能够稳定地输出晶体摆动场辐射,为寻找X激光或γ激光提供进一步理论分析。     

晶体摆动场的辐射衰减与能量增益

由于晶体弯曲、电子多重散射和晶格热振动引起的粒子退道,辐射同原子相互作用引起的电离损失,以及系统非线性引起的全局分叉与混沌行为等,晶体摆动场辐射面临的问题比自由电子激光要复杂得多。首先,引入晶体摆动场自发辐射谱分布,并在简谐近似下讨论了运动方程、系统增益和能量衰减。结果表明:一般情况下辐射谱只有少数几条谱线,而在简谐近似下,谱线只有一条。其次,指出了辐射能量比较高时,衰减是主要的,选择的晶体长度必须小于衰减长度,且可选择正电子或质子作炮弹;当辐射能量比较低时,退道是主要的,选择的晶体长度必须小于退道长度,且可选择重离子作炮弹。     

正弦平方势与小振幅近似下的弯晶沟道辐射

在理想情况下和经典力学框架内,引入正弦平方势,把粒子在弯晶中的运动方程化为具有外力矩的摆方程。并对系统的相平面特征进行了数值分析。在小振幅近似下,把粒子运动方程化为具有硬特性的弹簧-振子系统,用Jacobian椭圆函数和椭圆积分解析地给出系统的解和粒子运动周期。讨论了弯晶沟道辐射频率、无量纲偏转角和辐射谱的一般特征。指出利用沟道辐射作为激光的可能性。以正电子在碳单晶中沟道辐射为例进行了具体计算,得到了与其他工作基本一致的结果。     

超晶格量子阱的沟道辐射及其谱分布

在经典物理框架内和偶极近似下, 导出了超晶格量子阱沟道辐射频率和辐射谱分布。指出了对于自发辐射谱分布, 存在一个普适的线型因子, 而粒子的最大辐射能量与相对论因子γ 有关, 且与γ3/2成正比。以正弦平方势为例进行了具体讨论。结果表明, 由于势阱深度和噪音的影响, 谐波数l只取少数几个值。超晶格量子阱沟道辐射只存在不多的几条谱线, 为进一步应用提供了可能。最后, 还给出了一种可能的实验方案, 讨论了如何利用弯晶把超晶格量子阱的沟道辐射改造为相干辐射。 In the frame of classical physics and the dipole approximation the radiation frequency and the spectral distribution are derived for the channeling radiation of a charged particle in a superlattice quantum well. It indicated that there is a line type factor f(ξ) suited to various cases in the spontaneous radiations spectrum. Results also show that the maximum radiation energy is proportional to γ3/2 , but the relativistic effects have double effects in the spontaneous radiation of a charged particle. The case for the sine squared potential is discussed specifically. The harmonic number can be defined as a few variable values by the effects of the potential well depth and noise. In general there is a few spectral lines in the channeling radiation spectrum for the superlattice quantum well, and possibilities are provided for further application. Finally, a possible experimental scheme is proposed, and it is discussed that how to transform the channeling radiation in the quantum well into the cohenent radiation by the bent crystal.     

Spectral method in axial channeling theory

The energy quantization of transverse particle motion in continuous potentials of atomic chains and planes can occur when fast charged particles travel in crystals. In the proposed paper, the energy levels of electrons moving in the mode of axial channeling in a system of parallel atomic chains have been found (Si crystal [110] chains have been used as an example). The energy eigenvalues were determined numerically using the so-called spectral method, which shows itself to good advantage in the problem of the plane channeling of charged particles in crystals.     

Chaotic behavior of channeling particles

Channeling describes the collimated motion of energetic charged particles along the lattice plane or axis in a crystal. The energetic particles are steered through the channels formed by strings of atomic constituents in the lattice. In the case of planar channeling, the motion of a charged particle between the atomic planes can be periodic or quasiperiodic, such as a simple oscillatory motion in the transverse direction. In practice, however, the periodic motion of the channeling particles can be accompanied by an irregular, chaotic behavior. In this paper, the Moliere potential, which is considered as a good analytical approximation for the interaction of channeling particles with the rows of atoms in the lattice, is used to simulate the channeling behavior of positively charged particles in a tungsten (100) crystal plane. By appropriate selection of channeling parameters, such as the projectile energy E(0) and incident angle psi(0), the transition of channeling particles from regular to chaotic motion is demonstrated. It is argued that the fine structures that appear in the angular scan channeling experiments are due to the particles' chaotic motion.     

Parametric channeling and collapse of beams of charged particles with internal structure in crystals: 2. Parametric processes during channeling of atomic ions, nuclei, and relativistic electrons in crystals

Features of parametric effects during channeling of atomic ions, nuclei, and relativistic electrons (positrons) in crystals were considered. It was shown that parametric coupling between ion channeling states in the field of crystal axes and planes and electronic states in the ion volume leads to the possibility of “parametric collapse” of the beam, i.e., a decrease in the oscillation amplitude of the atomic ion in the channel due to periodic transfer of the ion oscillation energy to the inner electron of the atom. The same effect can be used to cool beams due to energy transfer to intrinsic nuclear states with low energy levels. It was shown that parametric cooling of beams with a decrease in the transverse energy can also occur during axial channeling of relativistic electron beams. This process results from the parametric coupling between channeling states, which are caused by the particle charge and electron spin states in an effective magnetic field induced in the moving coordinate system.