High power heating and current drive (H&CD) facilities are required to fulfil a number of functions in Next Step tokamaks such as ITER and in power plants. The main functions of the ITER H&CD systems are start-up assist; H-mode access; heating to ignition; supplementary heating for driven-burn and for controlled plasma shut-down; current drive for extended burn and access to steady-state regimes; performance optimisation, control of plasma instabilities and making the plasma rotate. This paper reviews recent progress with H&CD systems, which has largely come about in response to the needs of ITER [1-3]. We survey how the designs have been influenced by physics requirements and technical constraints (such as reliable c.w. operation with modular integrated port plug designs), and emphasise key outstanding issues. The four main candidate systems are: electron and ion cyclotron resonance frequency, lower hybrid, and neutral beam heating. These all have their own physics and technology advantages, and disadvantages, and their components are at various stages of development.
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机译:需要大功率加热和电流驱动(H&CD)设施来完成ITER等下一步托卡马克机以及发电厂中的许多功能。 ITER H&CD系统的主要功能是启动辅助。 H模式访问;加热点火;辅助加热,以驱动燃烧并控制等离子体关闭;当前为扩大烧伤和进入稳态制度的动力;性能优化,控制等离子体不稳定性以及使等离子体旋转。本文回顾了H&CD系统的最新进展,这在很大程度上是为满足ITER [1-3]的需求而做出的。我们调查了设计如何受到物理要求和技术约束(例如采用模块化集成端口插头设计的可靠连续运行)的影响,并强调了关键的突出问题。四个主要候选系统是:电子和离子回旋共振频率,较低的混合动力以及中性束加热。这些都有各自的物理和技术优势和劣势,并且它们的组件处于发展的各个阶段。
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