0000000000430587

AUTHOR

M. Yokoyama

showing 5 related works from this author

Major results from the first plasma campaign of the Wendelstein 7-X stellarator

2017

After completing the main construction phase of Wendelstein 7-X (W7-X) and successfully commissioning the device, first plasma operation started at the end of 2015. Integral commissioning of plasma start-up and operation using electron cyclotron resonance heating (ECRH) and an extensive set of plasma diagnostics have been completed, allowing initial physics studies during the first operational campaign. Both in helium and hydrogen, plasma breakdown was easily achieved. Gaining experience with plasma vessel conditioning, discharge lengths could be extended gradually. Eventually, discharges lasted up to 6 s, reaching an injected energy of 4 MJ, which is twice the limit originally agreed for t…

Magnetic confinementNuclear and High Energy PhysicsTechnology and EngineeringPlasma heatingCyclotron resonanceCONFINEMENT01 natural sciencesElectron cyclotron resonance010305 fluids & plasmaslaw.inventionPHYSICSNuclear physicsstellaratorcurrent drive; magnetic confinement; plasma heating; stellarator; Nuclear and High Energy Physics; Condensed Matter Physicslaw0103 physical sciencesddc:530010306 general physicstellaratorStellaratorPhysicsmagnetic confinementMagnetic confinement fusionplasma heatingcurrent drive;magnetic confinement;plasma heating;stellaratorPlasma530 PhysikCondensed Matter PhysicsTRANSPORTCurrent drivecurrent driveElectron temperaturePlasma diagnosticsAtomic physicsWendelstein 7-X[PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph]StellaratorNuclear Fusion
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Overview of first Wendelstein 7-X high-performance operation

2019

Abstract The optimized superconducting stellarator device Wendelstein 7-X (with major radius , minor radius , and plasma volume) restarted operation after the assembly of a graphite heat shield and 10 inertially cooled island divertor modules. This paper reports on the results from the first high-performance plasma operation. Glow discharge conditioning and ECRH conditioning discharges in helium turned out to be important for density and edge radiation control. Plasma densities of with central electron temperatures were routinely achieved with hydrogen gas fueling, frequently terminated by a radiative collapse. In a first stage, plasma densities up to were reached with hydrogen pellet injec…

TechnologyCONFINEMENT01 natural sciencesimpurities010305 fluids & plasmaslaw.inventionECR heatingDivertorDENSITY LIMITlawData_FILESGeneralLiterature_REFERENCE(e.g.dictionariesencyclopediasglossaries)004 Datenverarbeitung; InformatikPhysicsGlow dischargeDivertorCondensed Matter PhysicsContent (measure theory)ComputingMethodologies_DOCUMENTANDTEXTPROCESSINGElectron temperatureAtomic physicsddc:620StellaratorImpuritiesNuclear and High Energy PhysicsTechnology and Engineeringplasma performancechemistry.chemical_elementAtmospheric-pressure plasmaPHYSICSstellaratorPhysics::Plasma PhysicsNBI heating0103 physical sciencesdivertor010306 general physicsHeliumStellaratorPlasma performanceturbulenceFísicaW7-XTurbulenceTheoryofComputation_MATHEMATICALLOGICANDFORMALLANGUAGESchemistryddc:004ddc:600Energy (signal processing)SYSTEMNuclear Fusion
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Technical challenges in the construction of the steady-state stellarator Wendelstein 7-X

2013

The next step in the Wendelstein stellarator line is the large superconducting device Wendelstein 7-X, currently under construction in Greifswald, Germany. Steady-state operation is an intrinsic feature of stellarators, and one key element of the Wendelstein 7-X mission is to demonstrate steady-state operation under plasma conditions relevant for a fusion power plant. Steady-state operation of a fusion device, on the one hand, requires the implementation of special technologies, giving rise to technical challenges during the design, fabrication and assembly of such a device. On the other hand, also the physics development of steady-state operation at high plasma performance poses a challeng…

Nuclear and High Energy PhysicsSteady state (electronics)LIMIT ANALYSISPLASMANuclear engineeringMAGNET SYSTEMPlasmaFusion powerCondensed Matter PhysicsW7-XElectron cyclotron resonancelaw.inventionPHYSICSData acquisitionHeating systemlawWendelstein 7-XStellarator
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Simultaneous measurement of the muon neutrino charged-current cross section on oxygen and carbon without pions in the final state at T2K

2020

Authors: K. Abe,56 N. Akhlaq,45 R. Akutsu,57 A. Ali,32 C. Alt,11 C. Andreopoulos,54,34 L. Anthony,21 M. Antonova,19 S. Aoki,31 A. Ariga,2 T. Arihara,59 Y. Asada,69 Y. Ashida,32 E. T. Atkin,21 Y. Awataguchi,59 S. Ban,32 M. Barbi,46 G. J. Barker,66 G. Barr,42 D. Barrow,42 M. Batkiewicz-Kwasniak,15 A. Beloshapkin,26 F. Bench,34 V. Berardi,22 L. Berns,58 S. Bhadra,70 S. Bienstock,53 S. Bolognesi,6 T. Bonus,68 B. Bourguille,18 S. B. Boyd,66 A. Bravar,13 D. Bravo Berguño,1 C. Bronner,56 S. Bron,13 A. Bubak,51 M. Buizza Avanzini ,10 T. Campbell,7 S. Cao,16 S. L. Cartwright,50 M. G. Catanesi,22 A. Cervera,19 D. Cherdack,17 N. Chikuma,55 G. Christodoulou,12 M. Cicerchia,24,† J. Coleman,34 G. Collazu…

Fermi gasPhysics::Instrumentation and DetectorsMonte Carlo methodmeasured [channel cross section]KAMIOKANDEmuon neutrino01 natural sciencesPhysics Particles & FieldsHigh Energy Physics - ExperimentHigh Energy Physics - Experiment (hep-ex)secondary beam [neutrino/mu][PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex]Particle Physics ExperimentsMuon neutrinoQDCharged currentQCPhysicsneutrino: energy spectrumJ-PARC LabPhysicsinteraction [neutrino nucleus]T2K experimentoscillation [neutrino]Monte Carlo [numerical calculations]suppressionNuclear & Particles PhysicskinematicsPhysical Sciences0202 Atomic Molecular Nuclear Particle and Plasma PhysicsGround statenumerical calculations: Monte Carlochannel cross section: measuredParticle Physics - Experiment530 PhysicsFOS: Physical sciencesAstronomy & Astrophysics530Nuclear physicsPionnear detector0103 physical sciencessimultaneous measurement0201 Astronomical and Space SciencesSCATTERINGddc:530010306 general physicsNeutrino oscillation0206 Quantum Physicscross section: charged currentMuonScience & Technologynucleus: ground stateNUCLEI010308 nuclear & particles physicsnucleus: targethep-excarbonenergy spectrum [neutrino]neutrino nucleus: interactionground state [nucleus]neutrino/mu: secondary beamtarget [nucleus]random phase approximationcharged current [cross section]High Energy Physics::Experimentneutrino: oscillationoxygenexperimental resultsPhysical Review D
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Measurement of inclusive charged current interactions on carbon in a few-GeV neutrino beam

2010

We report a measurement of inclusive charged current interactions of muon neutrinos on carbon with an average energy of 0.8 GeV using the Fermilab Booster Neutrino Beam. We compare our measurement with two neutrino interaction simulations: NEUT and NUANCE. The charged current interaction rates (product of flux and cross section) are extracted by fitting the muon kinematics, with a precision of 6%-15% for the energy dependent and 3% for the energy integrated analyses. We also extract charged current inclusive interaction cross sections from the observed rates, with a precision of 10%-30% for the energy dependent and 8% for the energy integrated analyses. This is the first measurement of the …

PhysicsNuclear and High Energy PhysicsParticle physicsMuonFOS: Physical sciencesElementary particleFermionHigh Energy Physics - ExperimentMassless particleNuclear physicsHigh Energy Physics - Experiment (hep-ex)High Energy Physics::ExperimentFermilabNeutrinoCharged currentLeptonPhysical Review D
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