Your search keyword '"Zohm, H"' showing total 10 results

1. Extension of the multi-frequency ECRH system at ASDEX upgrade

Author

Wagner D., Stober J., Kircher M., Leuterer F., Monaco F., Münich M., Schubert M., Zohm H., Gantenbein G., Jelonnek J., Thumm M., Meier A., Scherer T., Strauss D., Kasparek W., Lechte C., Plaum B., Zach A., Litvak A.G., Denisov G.G., Chirkov A., Malygin V., Popov L.G., Nichiporenko V.O., Myasnikov V.E., Tai E.M., Solyanova E.A., and Malygin S.A.

Subjects

Physics, QC1-999

Published

2017

2. On the criteria guiding the design of the upper electron-cyclotron launcher for ITER

Author

Poli E., Angioni C., Casson F. J., Farina D., Figini L., Goodman T. P., Maj O., Sauter O., Weber H., Zohm H., Saibene G., and Henderson M. A.

Subjects

Physics, QC1-999

Abstract

Electron cyclotron waves injected from an antenna located in the upper part of the vessel will be employed in ITER to controlMHD instabilities, particularly neoclassical tearingmodes (NTMs). The derivation of the NTM stabilization criteria used up to now to guide the optimization of the launcher is reviewed in this paper and their range of validity elucidated. Possible effects leading to a deterioration of the predicted performance through a broadening of the EC deposition profile are discussed. The most detrimental effect will likely be the scattering of the EC beams from density fluctuations, resulting in a beam broadening in the 100% range. The combined impact of these effects with that of beam misalignment (with respect to the targeted surface) is discussed for a time slice of the standard Q = 10 H-mode scenario.

Published

2015

3. High power ECRH and ECCD in moderately collisional ASDEX Upgrade Hmodes and status of EC system upgrade

Author

Stober J., Sommer F., Angioni C., Bock A., Fable E., Leuterer F., Monaco F., Müller F., Münich S., Petzold B., Poli E., Schubert M., Schütz H., Wagner D., Zohm H., Kasparek W., Plaum B., Meier A., Scherer Th., Strauß D., Jelonnek J., Thumm M., Litvak A., Denisov G.G., Chirkov A.V., Tai E.M., Popov L.G., Nichiporenko V.O., Myasnikov V.E., Soluyanova E.A., and Malygin V.

Subjects

Physics, QC1-999

Abstract

This contribution deals with H-modes with significant heat exchange between electrons and ions, but which can still show large differences between electron and ion-temperatures especially inside half minor radius. These conditions are referred to as moderately collisional. A systematic study shows that an increasing fraction of electron heating increases the transport in the ion channel mainly due to the dependence of the ITG dominated ion transport on the ratio Te/Ti in agreement with modeling. The rotational shear in the plasmas under study was so small that it hardly influences ITG stability, such that variations of the rotation profile due to a change of the heating method were of minor importance. These findings connect to studies of advanced tokamak scenarios using ECCD as a tool to modify the q-profile. The electron heating connected to the ECCD tends to increase the transport in the ion channel quite in contrast to the goal to operate at reduced current but with increased confinement. The confinement only increases as the fraction of ion heating is increased by adding more NBI. An ITER case was modeled as well. Due to the larger value of νei ・ τE the ratio Te/Ti is only moderately reduced even with strong electron heating and the confinement reduction is small even for the hypothetic case of using only ECRH as additional heating. Finally the paper discusses the ongoing upgrade of the AUG ECRH-system.

Published

2015

4. Feedback-controlled NTM stabilization on ASDEX Upgrade

Author

Stober J., Barrera L., Behler K., Bock A., Buhler A., Eixenberger H., Giannone L., Kasparek W., Maraschek M., Mlynek A., Monaco F., Poli E., Rapson C.J., Reich M., Schubert M., Treutterer W., Wagner D., and Zohm H.

Subjects

Physics, QC1-999

Abstract

On ASDEX Upgrade a concept for real-time stabilization of NTMs has been realized and successfully applied to (3,2)- and (2,1)-NTMs. Since most of the work has meanwhile been published elsewhere, a short summary with the appropriate references is given. Limitations, deficits and future extensions of the system are discussed. In a second part the recent work on using modulated ECCD for NTM stabilisation is described in some detail. In these experiments ECCD power is modulated according to a magnetic footprint of the rotating NTM. In agreement with earlier results it could be shown that O-point heating reduces the necessary average power for stabilisation whereas X-point heating hampers stabilisation. Although this modulated scheme is not relevant for routine NTM stabilisation on ASDEX Upgrade it may be mandatory for ITER or DEMO. On ASDEX Upgrade it has been re-developed to demonstrate the usage of a FAst DIrectional Switch to continously heat the O-point of the rotating island with only one gyrotron switching between two launchers which target the mode at locations separated in phase by 180 degrees as described in [1].

Published

2015

5. Transport analysis of high radiation and high density plasmas in the ASDEX Upgrade tokamak

Author

Casali L., Bernert M., Dux R., Fischer R., Kallenbach A., Kurzan B., Lang P., Mlynek A., McDermott R.M., Ryter F., Sertoli M., Tardini G., and Zohm H.

Subjects

Physics, QC1-999

Abstract

Future fusion reactors, foreseen in the “European road map” such as DEMO, will operate under more demanding conditions compared to present devices. They will require high divertor and core radiation by impurity seeding to reduce heat loads on divertor target plates. In addition, DEMO will have to work at high core densities to reach adequate fusion performance. The performance of fusion reactors depends on three essential parameters: temperature, density and energy confinement time. The latter characterizes the loss rate due to both radiation and transport processes. The DEMO foreseen scenarios described above were not investigated so far, but are now addressed at the ASDEX Upgrade tokamak. In this work we present the transport analysis of such scenarios. Plasma with high radiation by impurity seeding: transport analysis taking into account the radiation distribution shows no change in transport during impurity seeding. The observed confinement improvement is an effect of higher pedestal temperatures which extend to the core via stiffness. A non coronal radiation model was developed and compared to the bolometric measurements in order to provide a reliable radiation profile for transport calculations. High density plasmas with pellets: the analysis of kinetic profiles reveals a transient phase at the start of the pellet fuelling due to a slower density build up compared to the temperature decrease. The low particle diffusion can explain the confinement behaviour.

Published

2014

6. Assessment of Electron-Cyclotron-Current-Drive-Assisted Operation in DEMO

Author

Marushchenko N.B., Figini L., Farina D., Zohm H., Tardini G., Fable E., Poli E., and Porte L.

Subjects

Physics, QC1-999

Abstract

The achievable efficiency for external current drive through electron-cyclotron (EC) waves in a demonstration tokamak reactor is discussed. Two possible reactor designs, one for steady state and one for pulsed operation, are considered. It is found that for midplane injection the achievable current drive efficiency is limited by secondharmonic absorption at levels consistent with previous studies. Propagation through the second-harmonic region can be reduced by moving the launch position to the high-field side (this can be obtained by injecting the beam from an upper port in the vacuum vessel). In this case, beam tracing calculations deliver values for the EC current drive efficiency approaching those usually reported for neutral beam current drive.

Published

2012

7. ECRH on ASDEX Upgrade - System Status, Feed-Back Control, Plasma Physics Results

Author

Flamm J., Vaccaro A., Strauβ D., Scherer Th., Meier A., Stroth U., Kasparek W., Zohm H., Schütz H., Schubert M., Poli E., Münich M., Müller S., Mlynek A., Marascheck M., Monaco F., Leuterer F., Herrmann A., Gianone L., Wagner D., Treutterer W., Sommer F., Reich M., Höhnle H., Bock A., Stober J., Thumm M., Litvak A., Denisov G.G., Chirkov A.V., Tai E.M., Popov L.G., Nichiporenko V.O., Myasnikov V.E., Soluyanova E.A., and Malygin S.A.

Subjects

Physics, QC1-999

Abstract

The ASDEX Upgrade (AUG) ECRH system now delivers a total of 3.9 MW to the plasma at 140 GHz. Three new units are capable of 2-frequency operation and may heat the plasma alternatively with 2.1 MW at 105 GHz. The system is routinely used with X2, O2, and X3 schemes. For Bt = 3.2 T also an ITER-like O1-scheme can be run using 105 GHz. The new launchers are capable of fast poloidal movements necessary for real-time control of the location of power deposition. Here real-time control of NTMs is summarized, which requires a fast analysis of massive data streams (ECE and Mirnov correlation) and extensive calculations (equilibria, ray-tracing). These were implemented at AUG using a modular concept of standardized real-time diagnostics. The new realtime capabilities have also been used during O2 heating to keep the first reflection of the non-absorbed beam fraction on the holographic reflector tile which ensures a well defined second pass of the beam through the central plasma. Sensors for the beam position are fast thermocouples at the edge of the reflector tile. The enhanced ECRH power was used for several physics studies related to the unique feature of pure electron heating without fueling and without momentum input. As an example the effect of the variation of the heating mix in moderately heated H-modes is demonstrated using the three available heating systems, i.e. ECRH, ICRH and NBI. Keeping the total input power constant, strong effects are seen on the rotation, but none on the pedestal parameters. Also global quantities as the stored energy are hardly modified. Still it is found that the central ion temperature drops as the ECRH fraction exceeds a certain threshold.

Published

2012

8. High power ECRH and ECCD in moderately collisional ASDEX U-pgrade Hmodes and status of EC system upgrade.

Author

Stober, J., Sommer, F., Angioni, C., Bock, A., Fable, E., Leuterer, F., Monaco, F., Müller, F., Münich, S., Petzold, B., Poli, E., Schubert, M., Schütz, H., Wagner, D., Zohm, H., Kasparek, W., Plaum, B., Meier, A., Scherer, Th., and Strauß, D.

Subjects

HEAT exchangers, ELECTRON research, IONS, COLLISIONS (Nuclear physics), TOKAMAKS

Abstract

This contribution deals with H-modes with significant heat exchange between electrons and ions, but which can still show large differences between electron and ion-temperatures especially inside half minor radius. These conditions are referred to as moderately collisional. A systematic study shows that an increasing fraction of electron heating increases the transport in the ion channel mainly due to the dependence of the ITG dominated ion transport on the ratio Te/Ti in agreement with modeling. The rotational shear in the plasmas under study was so small that it hardly influences ITG stability, such that variations of the rotation profile due to a change of the heating method were of minor importance. These findings connect to studies of advanced tokamak scenarios using ECCD as a tool to modify the q-profile. The electron heating connected to the ECCD tends to increase the transport in the ion channel quite in contrast to the goal to operate at reduced current but with increased confinement. The confinement only increases as the fraction of ion heating is increased by adding more NBI. An ITER case was modeled as well. Due to the larger value of vei ⋅ τE the ratio Te/Ti is only moderately reduced even with strong electron heating and the confinement reduction is small even for the hypothetic case of using only ECRH as additional heating. Finally the paper discusses the ongoing upgrade of the AUG ECRH-system. [ABSTRACT FROM AUTHOR]

Published

2015

9. ECRH on ASDEX Upgrade - System Status, Feed-Back Control, Plasma Physics Results -

Author

Stober, J., primary, Bock, A., additional, Höhnle, H., additional, Reich, M., additional, Sommer, F., additional, Treutterer, W., additional, Wagner, D., additional, Gianone, L., additional, Herrmann, A., additional, Leuterer, F., additional, Monaco, F., additional, Marascheck, M., additional, Mlynek, A., additional, Müller, S., additional, Münich, M., additional, Poli, E., additional, Schubert, M., additional, Schütz, H., additional, Zohm, H., additional, Kasparek, W., additional, Stroth, U., additional, Meier, A., additional, Scherer, Th., additional, Strauβ, D., additional, Vaccaro, A., additional, Flamm, J., additional, Thumm, M., additional, Litvak, A., additional, Denisov, G.G., additional, Chirkov, A.V., additional, Tai, E.M., additional, Popov, L.G., additional, Nichiporenko, V.O., additional, Myasnikov, V.E., additional, Soluyanova, E.A., additional, and Malygin, S.A., additional

Published

2012

10. Assessment of Electron-Cyclotron-Current-Drive-Assisted Operation in DEMO

Author

Poli, E., primary, Fable, E., additional, Tardini, G., additional, Zohm, H., additional, Farina, D., additional, Figini, L., additional, Marushchenko, N.B., additional, and Porte, L., additional

Published

2012