Noriyuki Inoue scite author profile

The Large Helical Device (LHD) now under construction is a heliotron/torsatron device with a closed divertor system. The edge LHD magnetic structure has been studied in detail. A peculiar feature of the configuration is the existence of edge surface layers, a complicated three dimensional magnetic structure which does not, however, seem to hamper the expected divertor functions. Two divertor operational modes are being considered for the LHD experimenthigh density, cold radiative divertor operation as a safe heat removal scheme and high temperature divertor plasma operation. In the latter operation, a divertor plasma with a temperature of a few keV, generated by efficient pumping, is expected to lead to a significant improvement in core plasma confinement. Conceptual designs of the LHD divertor components are under way.

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Overview of the Large Helical Device project

Iiyoshi¹,

Komori²,

Ejiri³

et al. 1999

Nucl. Fusion

271

105

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OVERVIEW OF THE LARGE HELICAL DEVICE PROJECT. The Large Helical Device (LHD) has successfully started running plasma confinement experiments after a long construction period of eight years. During the construction and machine commissioning phases, a variety of milestones were attained in fusion engineering which successfully led to the first operation, and the first plasma was ignited on 31 March 1998. Two experimental campaigns are planned in 1998. In the first campaign, the magnetic flux mapping clearly demonstrated a nested structure of magnetic surfaces. The first plasma experiments were conducted with second harmonic 84 and 82.6 GHz ECH at a heating power input of 0.35 MW. The magnetic field was set at 1.5 T in these campaigns so as to accumulate operational experience with the superconducting coils. In the second campaign, auxiliary heating with NBI at 3 MW has been carried out. Averaged electron densities of up to 6 × 10 19 m-3 , central temperatures ranging from 1.4 IAEA-F1-CN-69/OV1/4 2 to 1.5 keV and stored energies of up to 0.22 MJ have been attained despite the fact that the impurity level has not yet been minimized. The obtained scarling of energy confinement time has been found to be consistent with the ISS95 scaling law with some enhancement.

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Improved reliability predictions in high permittivity dielectric oxide capacitors under high dc electric fields with oxygen vacancy induced electromigration

Randall

Maier

et al. 2013

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This paper attempts to improve upon the range of applicability and predictability of the empirical highly accelerated lifetime testing (HALT) equation that has been traditionally used to estimate time dependent breakdown strength performance in multilayer ceramic capacitors (MLCC) and integrated thin film capacitor structures. The present and traditional HALT equation shows evidence of being limited in thin dielectric layers under high fields, for example, in high capacitance MLCCs. When the traditional HALT equations are applied to MLCCs with higher operating electric fields, there are often field dependent voltage acceleration factors resulting in ambiguous data analysis. Here, we introduce a physical model to account for a critical ionic space charge accumulation preceded by the ionic hopping or electromigration of oxygen vacancies leading to an ultimate increase in leakage current typical of dielectric resistance degradation. Mean time to failure degradation data on experimental capacitors indicates superior predictions with the new non-linear equation than with the traditional HALT equation to provide more accurate and simpler testing in future components. It is further noted that this approach may be applicable to many capacitive devices that operate under a high bias and can have ionic space charge accumulation at interfaces prior to breakdown.

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Initial physics achievements of large helical device experiments

et al. 1999

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have started this year after a successful eight-year construction and test period of the fully superconducting facility. LHD investigates a variety of physics issues on large scale heliotron plasmas ͑Rϭ3.9 m, aϭ0.6 m͒, which stimulates efforts to explore currentless and disruption-free steady plasmas under an optimized configuration. A magnetic field mapping has demonstrated the nested and healthy structure of magnetic surfaces, which indicates the successful completion of the physical design and the effectiveness of engineering quality control during the fabrication. Heating by 3 MW of neutral beam injection ͑NBI͒ has produced plasmas with a fusion triple product of 8ϫ10 18 keV m Ϫ3 s at a magnetic field of 1.5 T. An electron temperature of 1.5 keV and an ion temperature of 1.4 keV have been achieved. The maximum stored energy has reached 0.22 MJ, which corresponds to ͗␤͘ϭ0.7%, with neither unexpected confinement deterioration nor visible magnetohydrodynamics ͑MHD͒ instabilities. Energy confinement times, reaching 0.17 s at the maximum, have shown a trend similar to the present scaling law derived from the existing medium sized helical devices, but enhanced by 50%. The knowledge on transport, MHD, divertor, and long pulse operation, etc., are now rapidly increasing, which implies the successful progress of physics experiments on helical currentless-toroidal plasmas.

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Noriyuki Inoue

The Large Helical Device (LHD) helical divertor

Overview of the Large Helical Device project

Improved reliability predictions in high permittivity dielectric oxide capacitors under high dc electric fields with oxygen vacancy induced electromigration

Initial physics achievements of large helical device experiments

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