Introduction 9 FortiClient EMS components 9 Documentation 11 Getting started 12 Getting started with managing Windows, macOS, and Linux endpoints 12 Deploying FortiClient software to endpoints 12 Pushing configuration information to FortiClient 13 Relationship between FortiClient EMS, FortiGate, and FortiClient 14 Getting started with managing Chromebooks 18 Configuring FortiClient EMS for Chromebooks 18 Configuring the Google Admin console 18 Deploying a profile to Chromebooks 18 How FortiClient EMS and FortiClient work with Chromebooks 19 Installation preparation 20 System requirements 20 License types 21 FortiClient EMS 21 Component applications 24 Required services and ports 24 Management capacity 27 Hardware configuration when EMS and SQL Server run on same machine with no FortiGate connected 29 Hardware configuration when EMS and SQL Server run on different machines with no FortiGate connected 29 Hardware configuration when FortiGates are connected to EMS 30 FortiClient Telemetry security features 32 Server readiness checklist for installation 32 Upgrading from an earlier FortiClient EMS version 32 Upgrading EMS and FortiClient 33 Upgrading EMS from an earlier version 33 Install preparation for managing Chromebooks 34 Google Workspace account 34 SSL certificates 34 Installation and licensing 35 Downloading the installation file 35 Installing FortiClient EMS 35 Installing FortiClient EMS to specify SQL Server Enterprise or Standard instance 37 Installing FortiClient EMS using the CLI 40 Allowing remote access to FortiClient EMS and using custom port numbers 42 Customizing the SQL Server Express install directory 43 Starting FortiClient EMS and logging in 43 Configuring EMS after installation 44 Licensing FortiClient EMS 45
单光子和固态颜色中心之间的非线性相互作用是量子科学中许多应用的核心[1,2],例如实现量子互联网[3,4]。尤其是,钻石中的彩色中心已启用了这个方向的高级演示,显示了多键量子网络操作[5,6],内存增强的通信[7]和可扩展的芯片载荷混合动力集成[8]。Among the diamond color centers, the tin-vacancy center (SnV) has recently emerged as a promising qubit platform, as it combines the inversion symmetry of group-IV color centers [9,10] , allowing for integration in nanophotonic structures, with good optical properties [11 – 14] and above-millisecond spin coherence at temperatures above 1 K [15,16] .将光子整合与自旋和光学控制结合的设备可以用作实现自旋photon大门的未来可伸缩构建块[17]。在通往这种可扩展的片上整合的路径上,将发射剂掺入纳米光子波导中[12,18],可以探索相干的发射极 - 光子相互作用,典型的波导 - 耦合系统[19,20]。与纳米光腔相比[21],波导具有宽带的优势,消除了腔体调整的挑战,并且在制造中具有明显更高的误差耐受性。 在这封信中,我们提出了一个由SNV中心组成的设备,该中心与纳米型钻石波导搭配锥形纤维通道,如图所示 1(a)。 感谢有效的耦合,双面访问和实时与纳米光腔相比[21],波导具有宽带的优势,消除了腔体调整的挑战,并且在制造中具有明显更高的误差耐受性。在这封信中,我们提出了一个由SNV中心组成的设备,该中心与纳米型钻石波导搭配锥形纤维通道,如图1(a)。感谢有效的耦合,双面访问和实时
