As the global energy economy makes the transition from fossil fuels toward cleaner alternatives, nuclear fusion becomes an attractive potential solution for satisfying growing needs. Fusion, the power source of the stars, has been the focus of active research since the early 1950s. While progress has been impressive-especially for magnetically confined plasma devices called tokamaks-the design of a practical power plant remains an outstanding challenge. A key topic of current interest is microturbulence, which is believed to be responsible for the unacceptably large leakage of energy and particles out of the hot plasma core. Understanding and controlling this process is of utmost importance for operating current devices and designing future ones. In addressing such issues, the Gyrokinetic Toroidal Code (GTC) was developed to study the global influence of microturbulence on particle and energy confinement. It has been optimized on the IBM Blue Gene/L~(TM) (BGjL) computer, achieving essentially linear scaling on more than 30,000 processors. A full simulation of unprecedented phase-space resolution was carried out with 32,768 processors on the BG/L supercomputer located at the IBM T. J. Watson Research Center, providing new insights on the influence of collisions on microturbulence.
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机译:随着全球能源经济从化石燃料向更清洁替代能源的过渡,核聚变成为满足不断增长的需求的有吸引力的潜在解决方案。自1950年代初以来,作为恒星动力的聚变一直是积极研究的重点。尽管取得了令人瞩目的进步,尤其是对于被称为托卡马克的磁约束等离子体设备,但实际电厂的设计仍然是一个巨大的挑战。当前关注的一个关键主题是微湍流,据信微湍流是造成能量和颗粒从热等离子体核中大量泄漏的原因。了解和控制此过程对于操作当前设备和设计未来设备至关重要。为了解决这些问题,制定了《动力动力学环形码》(GTC),以研究微湍流对颗粒和能量限制的全球影响。它已在IBM Blue Gene / LTM(BGjL)计算机上进行了优化,可在30,000多个处理器上实现基本上线性的缩放。在IBM T.J. Watson研究中心的BG / L超级计算机上使用32,768个处理器对空前的相空间分辨率进行了全面模拟,从而提供了有关碰撞对微湍流影响的新见解。
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