Your search keyword '"C. Tichmann"' showing total 20 results

1. Finite element and higher order difference formulations for modelling heat transport in magnetised plasmas.

Author

Sibylle Günter, Karl Lackner, and C. Tichmann

Published

2007

2. Overview of ASDEX Upgrade results—development of integrated operating scenarios for ITER

Author

F. Serra, R. Pugno, S. Klose, A. Herrmann, B. Kurzan, K. Mank, R. Narayanan, Garrard Conway, E. Würsching, O. Gehre, Q. Yu, P. Merkel, U. Seidel, R. Kochergov, T. Eich, K. Krieger, A. Bergmann, M. G. Pacco-Düchs, F. Ryter, C. F. Maggi, M. Balden, P. Martin, R. Riedl, Philipp Lauber, Frank Jenko, I. Radivojevic, L. Giannone, M. Maraschek, B. Zaniol, G. Haas, A. Mück, Gerhard Raupp, C. Tichmann, R. Merkel, H. F. Meyer, E. Strumberger, Martin Jakobi, D. Zasche, G. Becker, M. Garcia Munoz, K. Lackner, Y.P. Chen, W. Sandmann, O. J. W. F. Kardaun, K.-H. Steuer, Analiza M. Silva, F. Braun, A. G. Peeters, O. Gruber, F. Leuterer, A. Lyssoivan, W. Suttrop, A. Kallenbach, V. Mertens, K. K. Kirov, Bruce D. Scott, F. Wesner, Y.-S. Na, M. Münich, E. Quigley, C. Angioni, R. Lorenzini, Ivan Bizyukov, Michael Kaufmann, S. Kálvin, H. P. Zehrfeld, K.H. Behringer, W. Becker, Yasutaro Nishimura, A. Carlson, Daisuke Nishijima, M. Mayer, Hajime Urano, S. Cirant, A. Manini, T. Ribeiro, D. Borba, K. Engelhardt, B. Streibl, Junghee Kim, K. Dimova, H. Meister, M. Troppmann, S. Saarelma, Ursel Fantz, J. Hobirk, S. D. Pinches, F. Monaco, Emanuele Poli, Sheena Menmuir, Marco Brambilla, W. Kraus, A. Geier, H. Maier, S. Schweizer, G. Schramm, D. Merkl, S. W. Yoon, R. Neu, E. Speth, R. Bilato, A. V. Chankin, Thomas Zehetbauer, M. Tsalas, Julia Fuchs, M. Huart, J. Gafert, Fernando Meo, Alexander Kendl, T. Bolzonella, R. Drube, R. Dux, G. Tardini, K. Borrass, B. Heger, G. Pautasso, H. D. Murmann, Th. Pütterich, J. Chen, D. Meisel, K. Behler, J. Schirmer, V. Rohde, Wolf-Dieter Schneider, A. Lohs, G. Gantenbein, K. F. Mast, C. V. Atanasiu, G. Schall, A. Stäbler, A. Buhler, H. W. Müller, P. Varela, D. Strintzi, V. Bobkov, K. Gal, A. C. C. Sips, A. Jacchia, H. Kollotzek, Peter Lang, J. M. Santos, W. Treutterer, M. Apostoliceanu, M. Zilker, J. Neuhauser, M. Reich, P. Franzen, Tilman Dannert, J. Roth, H.-U. Fahrbach, Bernd Heinemann, M. E. Manso, D. A. Hartmann, C. Sihler, J. Stober, L. Fattorini, Isabel L. Nunes, H. Zohm, M. Kick, D. Wagner, A. Keller, Martin Laux, Jari Likonen, Taina Kurki-Suonio, E. Posthumus-Wolfrum, D. P. Coster, J. Schweinzer, G. Kocsis, M. Y. Ye, H. Hohenöcker, H. B. Schilling, C. Konz, P. Mantica, V. Igochine, G. Neu, Sibylle Günter, G. V. Pereverzev, L. D. Horton, Patrick J. McCarthy, M. Foley, A. Lorenz, and J.-M. Noterdaeme

Subjects

Nuclear and High Energy Physics, Materials science, Tokamak, Nuclear engineering, Automatic frequency control, fusion reactors, Electron, Parameter space, 7. Clean energy, 01 natural sciences, Particle transport, Electron cyclotron resonance, 010305 fluids & plasmas, ASDEX Upgrade, ITER, 0103 physical sciences, 010306 general physics, plasma, Magnetic confinement fusion, Condensed Matter Physics, fusion energy, ___, JET, Atomic physics, Control methods

Abstract

Significant progress has been made on ASDEX Upgrade during the last two years in the basic understanding of transport, in the extension of the improved H-mode in parameter space and towards an integrated operating scenario and in the development of control methods for major performance limiting instabilities. The important features were the understanding of particle transport and the control of impurity accumulation based on it, the satisfactory operation with predominantly tungsten-clad walls, the improved H-mode operation over density ranges and for temperature ratios covering (non-simultaneously) the ITER requirements on ν*, n/nGW and Te/Ti, the ELM frequency control by pellet injection and the optimization of NTM suppression by DC-ECCD through variation of the launching angle. From these experiments an integrated scenario has emerged which extrapolates to a 50% improvement in n T τ or a 30% reduction of the required current when compared with the ITER base-line assumptions, with moderately peaked electron and controllable high-Z density profiles.

Published

2005

3. A cross-tokamak neural network disruption predictor for the JET and ASDEX Upgrade tokamaks

Author

C.G Windsor, G Pautasso, C Tichmann, R.J Buttery, T.C Hender, JET EFDA Contributors, and the ASDEX Upgrade Team

Subjects

Nuclear and High Energy Physics, Jet (fluid), Tokamak, Safety factor, Artificial neural network, Computer science, Magnetic confinement fusion, Complex network, Condensed Matter Physics, Perceptron, law.invention, ASDEX Upgrade, law, Simulation

Abstract

First results are reported on the prediction of disruptions in one tokamak, based on neural networks trained on another tokamak. The studies use data from the JET and ASDEX Upgrade devices, with a neural network trained on just seven normalized plasma parameters. In this way, a simple single layer perceptron network trained solely on JET correctly anticipated 67% of disruptions on ASDEX Upgrade in advance of 0.01 s before the disruption. The converse test led to a 69% success rate in advance of 0.04 s before the disruption in JET. Only one overall time scaling parameter is allowed between the devices, which can be introduced from theoretical arguments. Disruption prediction performance based on such networks trained and tested on the same device shows even higher success rates (JET, 86%; ASDEX Upgrade, 90%), despite the small number of inputs used and simplicity of the network. It is found that while performance for networks trained and tested on the same device can be improved with more complex networks and many adjustable weights, for cross-machine testing the best approach is a simple single layer perceptron. This offers the basis of a potentially useful technique for large future devices such as ITER, which with further development might help to reduce disruption frequency and minimize the need for a large disruption campaign to train disruption avoidance systems.

Published

2005

4. The frequently interrupted regime of neoclassical tearing modes (FIR-NTMs): required plasma parameters and possibilities for its active control

Author

S Günter, M Maraschek, M. de Baar, D.F Howell, E Poli, E Strumberger, C Tichmann, ASDEX Upgrade Team, and Contributors to the EFDA-JET Workprogramme

Subjects

Physics, Nuclear and High Energy Physics, ASDEX Upgrade, Condensed matter physics, Rational surface, Plasma parameters, Tearing, Magnetic confinement fusion, Atmospheric-pressure plasma, Mechanics, Magnetohydrodynamics, Condensed Matter Physics, Bootstrap current

Abstract

The plasma parameters required for the occurrence of (3, 2) FIR-NTMs and thus good confinement properties at high normalized plasma pressure (βN) are investigated. Both on ASDEX Upgrade and on JET it is found that, with remarkable consistency between the devices, for a variety of plasma parameters in conventional current profile scenarios, this regime establishes itself for discharges with sufficient high normalized plasma pressure at mode onset, βN,onset > 2.3. An active triggering of this regime has been achieved by lowering the magnetic shear at the q = 4/3 rational surface. That way an ideal (4, 3) MHD mode is being destabilized, forcing the required three-wave coupling between the (3, 2) NTM, (1, 1) and (4, 3) mode activity.

Published

2004

5. Numerical investigations of axisymmetric equilibria with current holes

Author

E Strumberger, S Günter, J Hobirk, V Igochine, D Merkl, E Schwarz, C Tichmann, and the ASDEX Upgrade Team

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Field line, Magnetic confinement fusion, Atmospheric-pressure plasma, Plasma, Mechanics, Condensed Matter Physics, Magnetic field, law.invention, symbols.namesake, ASDEX Upgrade, Stark effect, Physics::Plasma Physics, law, symbols, Atomic physics

Abstract

In this paper, we present numerical tools convenient for the investigation of tokamak discharges with current holes. These tools allow the computation of fixed- and free-boundary equilibria with current holes, their representation in Boozer co-ordinates, the determination of the corresponding magnetic fields, field line tracing and also tracing of guiding centre orbits inside the hole. The numerical methods are tested by using two example configurations with different hole sizes. Furthermore, an equilibrium reconstruction of an ASDEX Upgrade discharge is performed. The motional Stark effect polarization angles of this discharge, which indicate a small current hole in the plasma centre, are reproduced by a numerical fit of various equilibrium parameters including pressure profile, rotational transform profile and poloidal coil currents. The resulting plasma parameters lie well inside the experimental error margins.

Published

2004

6. Numerical computation of magnetic fields of two- and three-dimensional equilibria with net toroidal current

Author

E. Strumberger, E. Schwarz, Sibylle Günter, C. Tichmann, H. P. Zehrfeld, and P. Merkel

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Toroid, Field line, Numerical analysis, Rotational symmetry, Magnetic confinement fusion, Mechanics, Condensed Matter Physics, Magnetic field, law.invention, Classical mechanics, Physics::Plasma Physics, law, Stellarator

Abstract

The MFBE_2001 code computes the magnetic field in a form suitable for field line tracing inside and outside the plasma boundary of two- and three-dimensional finite-β equilibria. It is a modified version of the Magnetic Field Solver for Finite-β Equilibria (MFBE) code which was developed for the investigation of stellarator equilibria without net toroidal current. The numerical method used in MFBE_2001 is based on the `virtual casing' principle which also allows the computation of magnetic fields of equilibria with net toroidal current, such as quasi-axisymmetric and tokamak equilibria. The numerical accuracy of the code is tested for an axisymmetric tokamak equilibrium and the corresponding three-dimensional one including the toroidal field ripple. For this purpose, the results obtained with the code system VMEC/NEMEC+MFBE_2001+GOURDON are compared with those computed with the axisymmetric equilibrium code DIVA.

Published

2002

7. On-line prediction and mitigation of disruptions in ASDEX Upgrade

Author

G Pautasso, C Tichmann, S Egorov, T Zehetbauer, O Gruber, M Maraschek, K.-F Mast, V Mertens, I Perchermeier, G Raupp, W Treutterer, C.G Windsor, and ASDEX Upgrade Team

Subjects

Nuclear and High Energy Physics, Tokamak, ASDEX Upgrade, law, Nuclear engineering, education, Environmental science, Plasma confinement, Condensed Matter Physics, Line (electrical engineering), law.invention

Abstract

An on-line predictor of the time to disruption has been installed on the ASDEX Upgrade tokamak. It is suitable either for avoidance of disruptions or for mitigation of those that are unavoidable. The prediction uses a neural network trained on eight plasma parameters and their time derivatives extracted from 99 disruptive discharges. The network was tested off-line over 500 discharges and was found to work reliably and to be able to predict the majority of the disruptions. The trained network was installed on-line, tested over 128 discharges and used to inject killer pellets to mitigate the disruption loads.

Published

2002

8. Fuzzy-neural approaches to the prediction of disruptions in ASDEX Upgrade

Author

F.C Morabito, M Versaci, G Pautasso, C Tichmann, and ASDEX Upgrade Team

Subjects

Nuclear and High Energy Physics, Tokamak, Artificial neural network, Event (computing), business.industry, Computer science, Magnetic confinement fusion, Fuzzy control system, Modular design, Condensed Matter Physics, computer.software_genre, law.invention, ASDEX Upgrade, law, Control system, Data mining, business, computer

Abstract

Disruption is a sudden loss of magnetic confinement that can cause damage to the machine walls and support structures. For this reason, it is of practical interest to be able to detect the onset of such an event early. A novel technique is presented of early prediction of plasma disruption in tokamak reactors which uses neural networks and `fuzzy' inference. The studies carried out in the work make use of an experimental database of disruptive shots made available by the ASDEX Upgrade Team. The main result of the work is that, in the limit of the available database, it is possible to predict the onset of the disruptive event sufficiently in advance in order to put the control system into action. The proposed system is a modular scheme that exploits a decomposition of the original database carried out in a proper way.

Published

2001

9. Overview of ASDEX Upgrade results

Author

O. Gruber, R. Arslanbekov, C. Atanasiu, A. Bard, G. Becker, W. Becker, M. Beckmann, K. Behler, K. Behringer, A. Bergmann, R. Bilato, D. Bolshukin, K. Borrass, H.-S. Bosch, B. Braams, M. Brambilla, R. Brandenburg, F. Braun, H. Brinkschulte, R. Brückner, B. Brüsehaber, K. Büchl, A. Buhler, H. Bürbaumer, A. Carlson, M. Ciric, G. Conway, D.P. Coster, C. Dorn, R. Drube, R. Dux, S. Egorov, W. Engelhardt, H.-U. Fahrbach, U. Fantz, H. Faugel, M. Foley, P. Franzen, P. Fu, J.C. Fuchs, J. Gafert, G. Gantenbein, O. Gehre, A. Geier, J. Gernhardt, E. Gubanka, A. Gude, S. Günter, G. Haas, D. Hartmann, B. Heinemann, A. Herrmann, J. Hobirk, F. Hofmeister, H. Hohenöcker, L. Horton, L. Hu, D. Jacobi, M. Jakobi, F. Jenko, A. Kallenbach, O. Kardaun, M. Kaufmann, A. Kendl, J.-W. Kim, K. Kirov, R. Kochergov, H. Kollotzek, W. Kraus, K. Krieger, B. Kurzan, G. Kyriakakis, K. Lackner, P.T. Lang, R.S. Lang, M. Laux, L. Lengyel, F. Leuterer, A. Lorenz, H. Maier, K. Mank, M.-E. Manso, M. Maraschek, K.-F. Mast, P.J. McCarthy, D. Meisel, H. Meister, F. Meo, R. Merkel, V. Mertens, J.P. Meskat, R. Monk, H.W. Müller, M. Münich, H. Murmann, G. Neu, R. Neu, J. Neuhauser, J.-M. Noterdaeme, I. Nunes, G. Pautasso, A.G. Peeters, G. Pereverzev, S. Pinches, E. Poli, R. Pugno, G. Raupp, T. Ribeiro, R. Riedl, S. Riondato, V. Rohde, H. Röhr, J. Roth, F. Ryter, H. Salzmann, W. Sandmann, S. Sarelma, S. Schade, H.-B. Schilling, D. Schlögl, K. Schmidtmann, R. Schneider, W. Schneider, G. Schramm, J. Schweinzer, S. Schweizer, B.D. Scott, U. Seidel, F. Serra, S. Sesnic, C. Sihler, A. Silva, A. Sips, E. Speth, A. Stäbler, K.-H. Steuer, J. Stober, B. Streibl, E. Strumberger, W. Suttrop, A. Tabasso, A. Tanga, G. Tardini, C. Tichmann, W. Treutterer, M. Troppmann, N. Tsois, W. Ullrich, M. Ulrich, P. Varela, O. Vollmer, U. Wenzel, F. Wesner, R. Wolf, E. Wolfrum, R. Wunderlich, N. Xantopoulos, Q. Yu, M. Zarrabian, D. Zasche, T. Zehetbauer, H.-P. Zehrfeld, A. Zeiler, and H. Zohm

Subjects

Nuclear and High Energy Physics, 0103 physical sciences, 010306 general physics, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas

Published

2001

10. Real-time disruption handling at ASDEX upgrade

Author

Gerhard Raupp, G. Pautasso, V. Mertens, D. Zasche, C. Tichmann, G. Neu, W. Treutterer, Th. Zehetbauer, A. Lorenz, and S. Egorov

Subjects

ComputingMilieux_GENERAL, Nuclear Energy and Engineering, ASDEX Upgrade, Soft landing, Artificial neural network, Computer science, Mechanical Engineering, Control system, Plasma control system, General Materials Science, Real-time operating system, Simulation, Civil and Structural Engineering

Abstract

A neural network for prediction of disruptions has been developed at ASDEX Upgrade with the goal to mitigate or avoid these. The novel idea is to compute the remaining time-to-disruption to indicate the stability level of the discharge. The neural network has been specified, trained and then implemented within the real-time plasma control system. The current version of the system terminates the discharge with an impurity pellet when the computed time-to-disruption falls below a threshold of 80 ms. Routine operation shows that disruptions are recognized reliably. Vessel currents and forces are considerably reduced. The system will be enhanced to avoid disruptions with a soft landing initiated in time.

Published

2001

11. Prediction and mitigation of disruptions in ASDEX Upgrade

Author

S.M. Egorov, F. Mast, G. Pautasso, M. Maraschek, Thomas Zehetbauer, V. Mertens, C. Tichmann, I. Perchermeier, Colin G. Windsor, A. Herrmann, and Julia Fuchs

Subjects

Nuclear and High Energy Physics, Tokamak, Artificial neural network, Nuclear engineering, Divertor, Auxiliary heating, Injector, Nuclear reactor, Fusion power, law.invention, Nuclear physics, Nuclear Energy and Engineering, ASDEX Upgrade, law, Environmental science, General Materials Science

Abstract

Disruptions in tokamaks are instabilities events which can damage the machine components. The avoidance and mitigation of these events is desirable in present machines as well as in Next Step devices (such as ITER). A neural network has been developed to predict the occurrence of disruptions caused by edge cooling mechanisms in ASDEX Upgrade. The network works reliably and is able to predict the majority (85%) of the disruptions. The neural network has been trained to predict the time interval up to the disruption and this makes it suitable to be used on-line either to avoid disruptions (by means of auxiliary heating and reduction of gas puffing) or to mitigate the unavoidable ones. For this last purpose, a solid pellet injector has been developed and tested; the injected impurity pellets have been shown to reduce the vertical forces and the conductive fluxes to the divertor.

Published

2001

12. Linear stability studies including resistive wall effects with the CASTOR/STARWALL code

Author

C. Tichmann, P. Merkel, E. Strumberger, and Sibylle Günter

Subjects

Physics, History, Partial differential equation, Differential equation, media_common.quotation_subject, Mathematical analysis, Rotational symmetry, Inertia, Computer Science Applications, Education, Classical mechanics, Physics::Plasma Physics, Magnetohydrodynamics, Eigenvalues and eigenvectors, media_common, Energy functional, Linear stability

Abstract

CASTOR/STARWALL is a code package for linear stability studies consisting of the CASTROR_3DW code, the STARWALL code, and a hybrid version of both codes named CASTOR3D that is currently under development. The latter solves an extended eigenvalue problem consisting of the plasma part defined by the weak form of the perturbed single-fluid MagnetoHydroDynamic (MHD) equations, and a vacuum part which is derived from an energy functional. This new code can describe wall resistivity and plasma inertia simultaneously. Furthermore, besides the so far used straight field line coordinates, additionally, general flux coordinates are implemented which are more appropriate for the description of instabilities located close to the separatrix (e.g. Edge Localized Modes (ELMs)). The formulation of the eigenvalue problem in the new coordinates is not limited to axisymmetric equilibria, so that, finally, stability studies of resistive and rotating, 3D equilibria should be possible. In this paper we will sketch the theory, report on the progress of the code development, and present first results.

Published

2014

13. Overview of ASDEX Upgrade results

Author

A. Kallenbach, J. Adamek, L. Aho-Mantila, S. Äkäslompolo, C. Angioni, C.V. Atanasiu, M. Balden, K. Behler, E. Belonohy, A. Bergmann, M. Bernert, R. Bilato, V. Bobkov, J. Boom, A. Bottino, F. Braun, M. Brüdgam, A. Buhler, A. Burckhart, A. Chankin, I.G.J. Classen, G.D. Conway, D.P. Coster, P. de Marné, R. D'Inca, R. Drube, R. Dux, T. Eich, N. Endstrasser, K. Engelhardt, B. Esposito, E. Fable, H.-U. Fahrbach, L. Fattorini, R. Fischer, A. Flaws, H. Fünfgelder, J.C. Fuchs, K. Gál, M. García Muñoz, B. Geiger, M. Gemisic Adamov, L. Giannone, C. Giroud, T. Görler, S. da Graca, H. Greuner, O. Gruber, A. Gude, S. Günter, G. Haas, A.H. Hakola, D. Hangan, T. Happel, T. Hauff, B. Heinemann, A. Herrmann, N. Hicks, J. Hobirk, H. Höhnle, M. Hölzl, C. Hopf, L. Horton, M. Huart, V. Igochine, C. Ionita, A. Janzer, F. Jenko, C.-P. Käsemann, S. Kálvin, O. Kardaun, M. Kaufmann, A. Kirk, H.-J. Klingshirn, M. Kocan, G. Kocsis, H. Kollotzek, C. Konz, R. Koslowski, K. Krieger, T. Kurki-Suonio, B. Kurzan, K. Lackner, P.T. Lang, P. Lauber, M. Laux, F. Leipold, F. Leuterer, A. Lohs, N.C. Luhmann, T. Lunt, A. Lyssoivan, H. Maier, C. Maggi, K. Mank, M.-E. Manso, M. Maraschek, P. Martin, M. Mayer, P.J. McCarthy, R. McDermott, H. Meister, L. Menchero, F. Meo, P. Merkel, R. Merkel, V. Mertens, F. Merz, A. Mlynek, F. Monaco, H.W. Müller, M. Münich, H. Murmann, G. Neu, R. Neu, B. Nold, J.-M. Noterdaeme, H.K. Park, G. Pautasso, G. Pereverzev, Y. Podoba, F. Pompon, E. Poli, K. Polochiy, S. Potzel, M. Prechtl, M.J. Püschel, T. Pütterich, S.K. Rathgeber, G. Raupp, M. Reich, B. Reiter, T. Ribeiro, R. Riedl, V. Rohde, J. Roth, M. Rott, F. Ryter, W. Sandmann, J. Santos, K. Sassenberg, P. Sauter, A. Scarabosio, G. Schall, K. Schmid, P.A. Schneider, W. Schneider, G. Schramm, R. Schrittwieser, J. Schweinzer, B. Scott, M. Sempf, F. Serra, M. Sertoli, M. Siccinio, A. Sigalov, A. Silva, A.C.C. Sips, F. Sommer, A. Stäbler, J. Stober, B. Streibl, E. Strumberger, K. Sugiyama, W. Suttrop, T. Szepesi, G. Tardini, C. Tichmann, D. Told, W. Treutterer, L. Urso, P. Varela, J. Vincente, N. Vianello, T. Vierle, E. Viezzer, C. Vorpahl, D. Wagner, A. Weller, R. Wenninger, B. Wieland, C. Wigger, M. Willensdorfer, M. Wischmeier, E. Wolfrum, E. Würsching, D. Yadikin, Q. Yu, I. Zammuto, D. Zasche, T. Zehetbauer, Y. Zhang, M. Zilker, H. Zohm, and Science and Technology of Nuclear Fusion

Subjects

PHYSICS, Nuclear and High Energy Physics, 0103 physical sciences, TOKAMAK, 010306 general physics, Condensed Matter Physics, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, REFLECTOMETRY

Abstract

The ASDEX Upgrade programme is directed towards physics input to critical elements of the ITER design and the preparation of ITER operation, as well as addressing physics issues for a future DEMO design. After the finalization of the tungsten coating of the plasma facing components, the re-availability of all flywheel-generators allowed high-power operation with up to 20 MW heating power at I p up to 1.2 MA. Implementation of alternative ECRH schemes (140 GHz O2- and X3-mode) facilitated central heating above n e = 1.2 × 1020 m−3 and low q 95 operation at B t = 1.8 T. Central O2-mode heating was successfully used in high P/R discharges with 20 MW total heating power and divertor load control with nitrogen seeding. Improved energy confinement is obtained with nitrogen seeding both for type-I and type-III ELMy conditions. The main contributor is increased plasma temperature, no significant changes in the density profile have been observed. This behaviour may be explained by higher pedestal temperatures caused by ion dilution in combination with a pressure limited pedestal and hollow nitrogen profiles. Core particle transport simulations with gyrokinetic calculations have been benchmarked by dedicated discharges using variations of the ECRH deposition location. The reaction of normalized electron density gradients to variations of temperature gradients and the T e/T i ratio could be well reproduced. Doppler reflectometry studies at the L–H transition allowed the disentanglement of the interplay between the oscillatory geodesic acoustic modes, turbulent fluctuations and the mean equilibrium E × B flow in the edge negative E r well region just inside the separatrix. Improved pedestal diagnostics revealed also a refined picture of the pedestal transport in the fully developed H-mode type-I ELM cycle. Impurity ion transport turned out to be neoclassical in between ELMs. Electron and energy transport remain anomalous, but exhibit different recovery time scales after an ELM. After recovery of the pre-ELM profiles, strong fluctuations develop in the gradients of n e and T e. The occurrence of the next ELM cannot be explained by the local current diffusion time scale, since this turns out to be too short. Fast ion losses induced by shear Alfvén eigenmodes have been investigated by time-resolved energy and pitch angle measurements. This allowed the separation of the convective and diffusive loss mechanisms.

Published

2011

14. Self-consistent three-dimensional computations of non-axisymmetric ITER equilibria

Author

C. Tichmann, E. Strumberger, P. Merkel, E. Schwarz, and Sibylle Günter

Subjects

Physics, Nuclear and High Energy Physics, Rotational symmetry, Perturbation (astronomy), Magnetic confinement fusion, Atmospheric-pressure plasma, Mechanics, Plasma, Blanket, Condensed Matter Physics, Magnetic field, Nuclear physics, Physics::Plasma Physics, Axial symmetry

Abstract

Three planned test blanket modules (TBMs) and 18 toroidal field coils break the axisymmetry of the ITER magnetic field. In this paper, the plasma response on these non-axisymmetric fields is studied quantitatively. For this purpose, self-consistent, three-dimensional, free-boundary equilibria of type ITER scenario 4 are computed. The resulting 3D equilibrium magnetic fields are then compared with the corresponding axisymmetric fields to which the vacuum perturbation fields are superimposed. The studies are performed for various normalized plasma pressures.

Published

2010

15. Addendum to papers from Axially Symmetric Divertor Experiment (ASDEX) Upgrade Team, published in Review of Scientific Instruments

Author

T. Eich, D. Yadikin, P. de Marne, Piero Martin, C. Tichmann, T. Lunt, K. Behler, A. Kammel, E. Strumberger, G. Tardini, K.H. Behringer, G. D. Conway, Bill Scott, F. Monaco, M. Rott, Manfred Zilker, A. Stäbler, K. Krieger, Taina Kurki-Suonio, G. Haas, G. Koscis, B. Streibl, R. Merkel, M. Mantsinen, L. Urso, B. Langer, A. Gude, A. Kirk, J. Stober, H. Doerk-Bendig, T. Hauff, M. Gemisic Adamov, G. Schall, H. Zohm, H.-J. Klingshirn, Karl Schmid, J. M. Santos, Emanuele Poli, K. McCormick, J. Neuhauser, A. Kagarmanov, J. Hobirk, D. Wagner, D. Zasche, Fernando Meo, A. Herrmann, Michael Kaufmann, W. Suttrop, E. Würsching, M. Reich, C. Angioni, G. Pautasso, N. Hicks, G. Antar, C. Wigger, B. Kurzan, H. Meister, Wolf-Dieter Schneider, V. Rohde, C. Vorpahl, Martin Laux, A. Lohs, Jari Likonen, M. Sertoli, D. P. Coster, P. Varela, O. J. W. F. Kardaun, J. Schweinzer, A. Lyssoivan, C. Konz, M. Püschel, M. Manso, L. Fattorini, S. Kálvin, K. Gal, H. Greuner, S. da Graca, Analiza M. Silva, Marco Brambilla, E. Wolfrum, K. Sassenberg, R. Bilato, M. Huart, R. Fischer, M. Münich, K. Mank, V. Mertens, H. Kollotzek, P. Merkel, L. Giannone, H. D. Murmann, N. Hammer, M. Sempf, M. Hölzl, M. Maraschek, Peter Lang, B. Reiter, Sibylle Günter, J. Roth, Lin Liu, H.-U. Fahrbach, Bernd Heinemann, P. Sauter, W. Treutterer, C. V. Atanasiu, I. Classen, U. Seidel, G. V. Pereverzev, Roman Schrittwieser, O. Gruber, R. Riedl, Cary Forest, Patrick J. McCarthy, A. Bergmann, Julia Fuchs, Philipp Lauber, V. Igochine, J. Adamek, F. Ryter, S. Potzel, Tobias Görler, M. Janzer, H. W. Müller, M. Brüdgam, F. Merz, E. Speth, A. Mlynek, M. Garcia-Munoz, F. Serra, E. Vainonen-Ahlgren, M. Balden, J.-M. Noterdaeme, M. Kick, H. F. Meyer, N. Endstrasser, A. V. Chankin, Gerhard Raupp, Mattia Siccinio, Frank Jenko, K.-H. Steuer, Alberto Bottino, K. Engelhardt, T. Pütterich, Q. Yu, R. Drube, R. Dux, A. Sigalov, K. Lackner, Christian Hopf, W. Sandmann, A. Scarabosio, A. Buhler, A. Kallenbach, Thomas Zehetbauer, T. Ribeiro, R. Neu, R. M. McDermott, M. Mayer, R. D’Inca, D. Holtum, F. Braun, G. Neu, B. Nold, J. E. Boom, D. Dodt, R. Stadler, S. Gori, V. Bobkov, M. Wischmeier, F. Leuterer, Peter Schneider, and W. Becker

Subjects

Scientific instrument, Physics, ASDEX Upgrade, Divertor, Nuclear engineering, Addendum, Axial symmetry, Instrumentation, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries)

Abstract

This addendum applies to papers authored by contributors from the Axially Symmetric Divertor Experiment (ASDEX) Upgrade Team published in Review of Scientific Instruments. This addendum provides the full list of ASDEX Upgrade Team contributors and their affiliations.

Published

2010

16. Plasma wall interaction and its implication in an all tungsten divertor tokamak

Author

Emanuele Poli, Y. R. Martin, L. Fattorini, Fernando Meo, M. Sertoli, G. Tardini, M. Garcia Munoz, T T Ribeiro, Qiang Yu, E. Vainonen-Ahlgren, Laure Vermare, G. Haas, K. Lackner, W. Sandmann, O. J. W. F. Kardaun, M. Rott, R. Merkel, K.-H. Steuer, Piero Martin, A. Kallenbach, P. de Marne, K. Gál, Alberto Bottino, N. Hicks, M. Gemisic-Adamov, Michael Kaufmann, Bruce D. Scott, A. Gude, J. Stober, H. Zohm, V. Mertens, H. D. Murmann, C. V. Atanasiu, K.H. Behringer, D. Wagner, V. Igochine, J.-M. Noterdaeme, Th. Pütterich, K. Sassenberg, A. Flaws, M. Püschel, F. Serra, G. Neu, H. Kollotzek, A. Bergmann, R. Pugno, H. W. Müller, W. Schustereder, K. McCormick, H. Meister, H. Greuner, R. Bilato, M. Huart, Wolf-Dieter Schneider, A. Lohs, R. Schrittwieser, W. Becker, F. Ryter, F. Merz, V. Bobkov, H. F. Meyer, M. Mlynek, Julia Fuchs, M. Mayer, C. F. Maggi, D. Holtum, F. Braun, Peter Lang, J. Hobirk, Taina Kurki-Suonio, A. C. C. Sips, S. da Graca, W. Suttrop, M. Balden, Marco Brambilla, T. Eich, H. Maier, J. M. Santos, M. Wischmeier, C. Tröster, Garrard Conway, E. Würsching, B. Nold, T. Bertoncelli, B. Reiter, M. Zilker, Ana Elisa Bauer de Camargo Silva, Ch. Hopf, C. Angioni, Sibylle Günter, A. Stäbler, R. Riedl, E. Speth, G. Kocsis, Thomas Zehetbauer, Philipp Lauber, S. Kálvin, J. Schirmer, G. V. Pereverzev, K. Engelhardt, C. Tichmann, E. Wolfrum, P. Varela, A. Manini, Patrick J. McCarthy, J. Harhausen, J. Roth, S. Gori, H.-U. Fahrbach, A. Scarabosio, Bernd Heinemann, L. D. Horton, M. E. Manso, Lin Liu, A. Schmid, P. Merkel, Rudolf Neu, D. Yadikin, L. Giannone, C. Konz, M. Maraschek, F. Monaco, E. Strumberger, R. Fischer, J. Fink, K. Mank, S. Dietrich, G. Pautasso, R. Drube, R. Dux, V. Rohde, A. Sigalov, A. Buhler, Martin Laux, Jari Likonen, D. P. Coster, J. Schweinzer, L. Urso, G. Schall, D. Zasche, Ursel Fantz, G. Schramm, A. V. Chankin, K. Behler, Gerhard Raupp, K. Krieger, O. Gruber, K. Dimova, S. Schweizer, J. Neuhauser, A. Herrmann, M. Reich, B. Kurzan, P. Franzen, U. Seidel, M. Kick, and W. Treutterer

Subjects

Tokamak, Materials science, Divertor, Facing Components, Transport, chemistry.chemical_element, Flux, Plasma, Effective radiated power, Tungsten, Condensed Matter Physics, law.invention, Nuclear Energy and Engineering, Alcator C-Mod, chemistry, ASDEX Upgrade, Erosion, law, Iter-Like Wall, Atomic physics, Asdex Upgrade Divertor, Operation

Abstract

ASDEX Upgrade has recently finished its transition towards an all-W divertor tokamak, by the exchange of the last remaining graphite tiles to W-coated ones. The plasma start-up was performed without prior boronization. It was found that the large He content in the plasma, resulting from DC glow discharges for conditioning, leads to a confinement reduction. After the change to D glow for inter-shot conditioning, the He content quickly dropped and, in parallel, the usual H-Mode confinement with H factors close to one was achieved. After the initial conditioning phase, oxygen concentrations similar to that in previous campaigns with boronizations could be achieved. Despite the removal of all macroscopic carbon sources, no strong change in C influxes and C content could be observed so far. The W concentrations are similar to the ones measured previously in discharges with old boronization and only partial coverage of the surfaces with W. Concomitantly it is found that although the W erosion flux in the divertor is larger than the W sources in the main chamber in most of the scenarios, it plays only a minor role for the W content in the main plasma. For large antenna distances and strong gas puffing, ICRH power coupling could be optimized to reduce the W influxes. This allowed a similar increase of stored energy as yielded with comparable beam power. However, a strong increase of radiated power and a loss of H-Mode was observed for conditions with high temperature edge plasma close to the antennas. The use of ECRH allowed keeping the central peaking of the W concentration low and even phases of improved H-modes have already been achieved.

Published

2007

17. Finite element and higher order difference formulations for modelling heat transport in magnetised plasmas

Author

C. Tichmann, Sibylle Günter, and K. Lackner

Subjects

Numerical Analysis, Diffusion equation, Physics and Astronomy (miscellaneous), Applied Mathematics, Numerical analysis, Mathematical analysis, Finite difference, Finite difference coefficient, Finite element method, Computer Science Applications, Computational Mathematics, Singularity, Classical mechanics, Modeling and Simulation, Coordinate singularity, Heat equation, Mathematics

Abstract

We present a finite element analogue to the second-order, finite difference scheme for the solution of the heat diffusion equation in strongly magnetised plasmas given in Gunter et al. S. Gunter et al., J. Comp. Phys. 209 (2005) 354]. Compared to standard finite element or finite difference formulations it strongly reduces the pollution of perpendicular heat fluxes by parallel ones even without resorting to field-aligned coordinates. We present both bi-linear and bi-quadratic versions of this scheme as well as a fourth-order extension of the original difference scheme of Gunter et al. (2005). In the second part of the paper, we address the formulation of the boundary conditions at walls with an oblique incidence of field lines and the treatment of the coordinate singularity at r=0 in cylindrical, or topologically equivalent coordinates with the reduced-pollution finite difference scheme. All tests shown indicate that both the finite-difference and the finite-element versions of the scheme should substantially alleviate the requirement for field-alignment of the coordinates over the realistic range of ??/?? in toroidal magnetic confinement devices.

Published

2007

18. Overview of ASDEX Upgrade results

Author

H. Zohm 1), C. Angioni 1), R. Arslanbekov 1), C. Atanasiu 2), G. Becker 1), W. Becker 1), K. Behler 1), K. Behringer 1), A. Bergmann 1), R. Bilato 1), V. Bobkov 1), D. Bolshukhin 1), T. Bolzonella 3), K. Borrass 1), M. Brambilla 1), F. Braun 1), A. Buhler 1), A. Carlson 1), G.D. Conway 1), D. P. Coster 1), R, Drube 1), R. Dux 1), S. Egorov 4), T. Eich 1), K. Engelhardt 1), H.-U. Fahrbach 1), U. Fantz 5), H. Faugel 1), K.H. Finken 6), M. Foley 7), P. Franzen 1), J. C. Fuchs 1), J. Gafert 1), K.B. Fournier 8), G. Gantenbein 9), O. Gehre 1), A. Geier 1), J. Gernhardt 1), T. Goodman 10), O. Gruber 1), A. Gude 1), S. G¨unter 1), G. Haas 1), D. Hartmann 1), B. Heger 5), B. Heinemann 1), A. Herrmann 1), J. Hobirk 1), F. Hofmeister 1), H. Hohen¨ocker 1), L. D. Horton 1), V. Igochine 1), A. Jacchia 11), M. Jakobi 1), F. Jenko 1), A. Kallenbach 1), O. Kardaun 1), M. Kaufmann 1), A. Keller 1), A. Kendl 1), J.-W. Kim 1), K. Kirov 1), R. Kochergov 1), H. Kollotzek 1), W. Kraus 1), K. Krieger 1), T. Kurki-Suonio 12) B. Kurzan 1), P. T. Lang 1), C. Lasnier, P. Lauber 1), M. Laux 1), A.W. Leonard 13), F. Leuterer 1), A. Lohs 1), A. Lorenz 1), R. Lorenzini 3), C. Maggi 1), H. Maier 1), K. Mank 1), M.-E. Manso 14), P. Mantica 12), M. Maraschek 1), E. Martines 3), K.-F. Mast 1), P. McCarthy 7), D. Meisel 1), H. Meister 1), F. Meo 1), P. Merkel 1), R. Merkel 1), D. Merkl 1), V. Mertens 1), F. Monaco 1), A.M¨uck 1), H.W.M¨uller 1), M.M¨unich 1), H.Murmann 1), Y.-S. Na 1), G. Neu 1), R. Neu 1), J. Neuhauser 1), F. Nguyen 15), D. Nishijima 1), Y. Nishimura 1), J.-M. Noterdaeme 1), I. Nunes 14), G. Pautasso 1), A. G. Peeters 1), G. Pereverzev 1), S. D. Pinches 1), E. Poli 1), M. Proschek 16), R. Pugno 1), E. Quigley 7), G. Raupp 1), M. Reich 1), T. Ribeiro 14), R. Riedl 1), V. Rohde 1), J. Roth 1), F. Ryter 1), S. Saarelma 12), W. Sandmann 1), A. Savtchkov 6), O. Sauter 10), S. Schade 1), H.-B. Schilling 1), W. Schneider 1), G. Schramm 1), E. Schwarz 1), J. Schweinzer 1), S. Schweizer 1), B. D. Scott 1), U. Seidel 1), F. Serra 14), S. Sesnic 1), C. Sihler 1), A. Silva 14), A. C. C. Sips 1), E. Speth 1), A. St¨abler 1), K.-H. Steuer 1), J. Stober 1), B. Streibl 1), E. Strumberger 1), W. Suttrop 1), A. Tabasso 1), A. Tanga 1), G. Tardini 1), C. Tichmann 1), W. Treutterer 1), M. Troppmann 1), H. Urano 1), P. Varela 14), O. Vollmer 1), D. Wagner 1), U. Wenzel 1), F. Wesner 1), E. Westerhof 17), R. Wolf 1), E. Wolfrum 1), E. W¨ursching 1), S.-W. Yoon 1), Q. Yu 1), D. Zasche 1), T. Zehetbauer 1), and H.-P. Zehrfeld 1)

Subjects

___

Abstract

Recent results from ASDEX Upgrade are presented. An improved understanding of energy and particle transport emerges in terms of a 'critical gradient' model for the temperature gradients. Coupling this to particle diffusion explains most of the observed behaviour of the density profiles, in particular the finding that strong central heating reduces the tendency for density profile peaking. Internal transport barriers with Te and Ti in excess of 20 keV (but not simultaneously) have been achieved. By shaping the plasma, a regime with small type II ELMs has been established. Here, the maximum power deposited on the target plates was greatly reduced at constant average power. Also, an increase of the ELM frequency by injection of shallow pellets was demonstrated. ELMfree operation is possible in the QH-mode regime previously found in DIII-D which has also been established on ASDEX Upgrade. Regarding stability, a regime with benign NTMs was found. During ECCD stabilisation of NTMs, bN could be increased well above the usual onset level without a reappearance of the NTM. ECRH and ECCD have also been used to control the sawtooth repetition frequency at a moderate fraction of the total heating power. The inner wall of the ASDEX Upgrade vessel has increasingly been covered with tungsten without detrimental effects on plasma performance. Regarding scenario integration, a scenario with a large fraction of noninductively driven current ( 50%), but without internal tranport barrier has been established. It combines improved confinement (tE=tITER98 1:2) and stability (bN 3:5) at high Greenwald fraction (ne=nGW 0:85) in steady state and with type II ELMy edge

Published

2003

19. MHD instabilities in 3D tokamaks

Author

Sibylle Günter, C. Tichmann, and E. Strumberger

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Computation, Ripple, Perturbation (astronomy), Fluid mechanics, Mechanics, Blanket, Condensed Matter Physics, Instability, law.invention, Classical mechanics, law, Magnetohydrodynamics

Abstract

Three-dimensional, ideal MHD tokamak equilibria are computed with the free-boundary NEMEC code, and their stability properties are investigated with the CAS3DN code, which is an ideal, linear MHD code. Numerical problems are discussed in detail by means of a test equilibrium with a large helical core. Further computations are performed for AUG-type equilibria perturbed by resonant magnetic perturbation (RMP) fields, and an ITER scenario taking into account the toroidal field ripple and perturbation fields caused by test blanket modules (TBMs). Moreover, a quantitative measure of the corrugation of the flux surfaces is introduced. It is found that the contour of the corrugation on equilibrium flux surfaces reflect the ideal kink structures of rational-q surfaces, and the periodicity of the external perturbation fields. Both stabilizing and destabilizing effects of the RMP fields, and the influence of the TBMs on the stability properties are observed.

Published

2014

20. Steady state advanced scenarios at ASDEX Upgrade

Author

Michael Kaufmann, H. D. Murmann, Thomas Zehetbauer, Dirk Hartmann, Marco Brambilla, W. Kraus, J. Neuhauser, S. Riondato, H. Maier, J. Gafert, F. Leuterer, D. Merkl, A. Lorenz, J. Gernhardt, R. Riedl, J.-M. Noterdaeme, H. W. Müller, Philipp Lauber, Julia Fuchs, W. Becker, A. Bergmann, Gerhard Raupp, Ana Elisa Bauer de Camargo Silva, F. Ryter, J. Stober, A. C. C. Sips, H. Zohm, D. Meisel, O. J. W. F. Kardaun, K. K. Kirov, R. Kochergov, C. F. Maggi, P. Franzen, D. Wagner, S. D. Pinches, Wolf-Dieter Schneider, A. Lohs, Alexander Kendl, G. Pautasso, H. Kollotzek, V. Rohde, R. Arslanbekov, U. Wenzel, K. Krieger, Martin Jakobi, W. Treutterer, Sibylle Günter, A. Gude, T. Ribeiro, G. Neu, F. Hofmeister, Frank Jenko, T. Eich, F. Wesner, G. Gantenbein, Bastiaan J. Braams, W. Suttrop, Peter Lang, S. Schade, E. Strumberger, H. P. Zehrfeld, G. V. Pereverzev, L. D. Horton, K. Engelhardt, Patrick J. McCarthy, O. Vollmer, F. Braun, K. Mank, S.M. Egorov, M. Münich, S. Saarelma, A. Tabasso, M. Foley, Robert Wolf, G. Becker, C. Sihler, O. Gruber, K.-H. Steuer, A. G. Peeters, S. Schweizer, K.H. Behringer, R. Bilato, Bruce D. Scott, Helmut Faugel, E. Wolfrum, M. Troppmann, Q. Yu, A. Keller, S. Sesnic, Martin Laux, G. Haas, R. Drube, A. Mück, E. Speth, R. Dux, D. P. Coster, O. Gehre, C. Tichmann, E. Quigley, B. Kurzan, J. Hobirk, J. Roth, R. Merkel, D. Bolshukhin, K. F. Mast, H.-U. Fahrbach, Bernd Heinemann, M. E. Manso, H. Hohenöcker, A. Stäbler, Emanuele Poli, H. B. Schilling, V. Mertens, F. Monaco, P. Varela, U. Seidel, A. Buhler, C. Atanasiu, Fernando Meo, B. Heger, K. B. Fournier, V. Igochine, M. Proschek, M. Maraschek, D. Jacobi, W. Sandmann, A. Kallenbach, A. Geier, G. Tardini, R. Neu, G. Schramm, K. Borrass, K. Behler, A. Tanga, D. Zasche, Y.-S. Na, Ursel Fantz, F. Serra, I. Nunes, H. Meister, B. Streibl, Junghee Kim, R. Pugno, Albrecht Herrmann, Garrard Conway, and E. Würsching

Subjects

Materials science, Tokamak, Divertor, Magnetic confinement fusion, Condensed Matter Physics, Electron cyclotron resonance, Neutral beam injection, law.invention, Bootstrap current, Nuclear Energy and Engineering, ASDEX Upgrade, law, Atomic physics, Edge-localized mode

Abstract

Recent experiments at ASDEX Upgrade have achieved advanced scenarios with high β N (>3) and confinement enhancement over ITER98(y, 2) scaling, H H98y2 = 1.1-1.5, in steady state. These discharges have been obtained in a modified divertor configuration for ASDEX Upgrade, allowing operation at higher triangularity, and with a changed neutral beam injection (NBI) system, for a more tangential, off-axis beam deposition. The figure of merit, β N H ITER89-P , reaches up to 7.5 for several seconds in plasmas approaching stationary conditions. These advanced tokamak discharges have low magnetic shear in the centre, with q on-axis near 1, and edge safety factor, q 95 in the range 3.3-4.5. This q-profile is sustained by the bootstrap current, NBI-driven current and fishbone activity in the core. The off-axis heating leads to a strong peaking of the density profile and impurity accumulation in the core. This can be avoided by adding some central heating from ion cyclotron resonance heating or electron cyclotron resonance heating, since the temperature profiles are stiff in this advanced scenario (no internal transport barrier). Using a combination of NBI and gas fuelling line, average densities up to 80-90% of the Greenwald density are achieved, maintaining good confinement. The best integrated results in terms of confinement, stability and ability to operate at high density are obtained in highly shaped configurations, near double null, with δ = 0.43. At the highest densities, a strong reduction of the edge localized mode activity similar to type II activity is observed, providing a steady power load on the divertor, in the range of 6 MW m -2 , despite the high input power used (> 10 MW).