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2s J?=1/2 + &epsilon;e? &rarr; 1s 2s&sup2; 2p&frac12; J?=1 &rarr; 1s&sup2; 2s J?=0 + &gamma;）作为示例。</p> <p> 对于这个特定过程，研究人员利用多组态Dirac-Hartree-Fock方法，对复合电子的不同自旋极化状态进行了详细计算。结果发现，复合电子的自旋极化对光子发射的线性极化P?（即第一Stokes参数）几乎没有影响，而极化P?（即第二Stokes参数）则强烈依赖于自旋极化。</p> <p> 此外，由于P?和P?的数值差异较大，导致获得了较大的极化倾斜角，该角度受到自旋极化的显著影响，尤其是在前向和后向光子发射时。这些极化行为与在高电荷离子与极化电子的辐射复合中获得的结果非常相似[Maiorova等人，Phys. Rev. A 107, 042814 (2023)]，并且可以使用现代X射线偏振计轻松观察到。</p> <p> 根据所获得的强烈依赖性，研究人员建议通过精确测量极化行为来诊断电子束的自旋极化状态，这种方法由于双电子复合（DR）过程的共振特性，比辐射复合[Maiorova等人，Phys. Rev. A 107, 042814 (2023)]的情况更为可行且具有前景。</p> <p> <strong>附：英文原文</strong></p> <p> Title: Spin polarization effect on linear polarization of photon emission following resonant electron capture of lithiumlike ions</p> <p> Author: Z. W. Wu, Y. Z. Wang</p> <p> Issue&amp;Volume: 2024/11/04</p> <p> Abstract: Dielectronic recombination (DR) of highly charged ions with spin-polarized electrons is studied within the framework of density-matrix theory. Special attention is paid to the question of how spin polarization of the recombined electron affects the polarization behavior of the subsequent photon emission. To address this question, while a general density-matrix formalism applicable to any DR process of arbitrary ions is presented, here, it is applied to a particular DR process (i.e., 1s&sup2; 2s J?=1/2 + &epsilon;e? &rarr; 1s 2s&sup2; 2p&frac12; J?=1 &rarr; 1s&sup2; 2s J?=0 + &gamma;) of lithiumlike ions as an example. For this particular process, detailed calculations are carried out for different spin polarization states of the recombined electron by utilizing the multiconfigurational Dirac-Hartree-Fock method. It is found that the spin polarization of the recombined electron hardly affects the linear polarization P₁ (i.e., the first Stokes parameter) of the photon emission, whereas the polarization P₂ (i.e., the second Stokes parameter) depends strongly on the spin polarization. In addition, owing to big differences in the magnitudes of P₁and P₂, a large polarization tilt angle is obtained that is remarkably affected by the spin polarization, especially for the forward and backward photon emission. These polarization behaviors are found to be rather similar to the results obtained in radiative recombination of highly charged ions with polarized electrons [Maiorova et al., Phys. Rev. A 107, 042814 (2023)] and can be readily observed using modern x-ray polarimeters. Based on the strong dependences obtained, we suggest that accurate measurements of the polarization behaviors can be applied to diagnosing the spin polarization state of electron beams, which is more feasible and promising than the case of radiative recombination [Maiorova et al., Phys. Rev. A 107, 042814 (2023)] owing to the resonance nature of DR processes.</p> <p> DOI: 10.1103/PhysRevA.110.052803</p> <p> Source: <a href="https://journals.aps.org/pra/abstract/10.1103/PhysRevA.110.052803">https://journals.aps.org/pra/abstract/10.1103/PhysRevA.110.052803</a></p> </p> <div class="remarks">期刊信息</div> <div class="dd"><p> <strong>Physical Review A：</strong>《物理评论A》，创刊于1970年。隶属于美国物理学会，最新IF：2.97<br /> <strong>官方网址：</strong><a href="https://www.nature.com/nchem/">https://journals.aps.org/pra/</a><br /> <strong>投稿链接：</strong><a href="https://mts-nchem.nature.com/cgi-bin/main.plex">https://authors.aps.org/Submissions/login/new</a></p> </div> </div> </div> <style> #footer{ background:#890f0e; text-align:center; padding:10px; color:#FFF; font-size:12px;} #footer a{color:#FFF; font-size:12px;} </style> <div id="footer"><a href="http://www.sciencenet.cn/aboutus/" target="_blank">关于我们</a> | <a href="http://www.sciencenet.cn/shengming.aspx" target="_blank">网站声明</a> | <a href="http://www.sciencenet.cn/tiaokuang.aspx" target="_blank">服务条款</a> | <a href="http://www.sciencenet.cn/contact.aspx" target="_blank">联系方式</a> | <a href="http://www.sciencenet.cn/RSS.aspx">RSS</a> | <a href="mailto:jubao@stimes.cn">举报</a> | <a href="https://stimes.sciencenet.cn/">中国科学报社</a> <br> <a href="https://beian.miit.gov.cn" target="_blank" > 京ICP备07017567号-12 </a>&nbsp;互联网新闻信息服务许可证10120230008 &nbsp;京公网安备 11010802032783<br>Copyright @ 2007-<script type="text/javascript">var Date22 = new Date();var year22 = Date22.getFullYear();document.write(year22);</script> 中国科学报社 All Rights Reserved<br> 地址：北京市海淀区中关村南一条乙三号&nbsp; 邮箱：blog@stimes.cn <br> <span style="display:none"> <script type="text/javascript"> var _bdhmProtocol = (("https:" == document.location.protocol) ? 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