Your search keyword '"Artaserse, Giovanni."' showing total 8 results

1. An overview of the software architecture of the plasma position, current and density realtime controller of the FTU

Author

Boncagni, Luca, Vitelli, Riccardo, Carnevale, Daniele, Galperti, Cristian, Artaserse, Giovanni, and Pucci, Daniele

Published

2014

2. First plasma operation of the enhanced JET vertical stabilisation system

Author

Rimini, Fernanda G., Crisanti, Flavio, Albanese, Raffaele, Ambrosino, Giuseppe, Ariola, Marco, Artaserse, Giovanni, Bellizio, Teresa, Coccorese, Vincenzo, De Tommasi, Gianmaria, De Vries, Peter, Lomas, Peter J., Maviglia, Francesco, Neto, Andre, Nunes, Isabel, Pironti, Alfredo, Ramogida, Giuseppe, Sartori, Filippo, Shaw, Stephen R., Tsalas, Maximos, Vitelli, Riccardo, and Zabeo, Luca

Published

2011

3. Installation and commissioning of the JET-EP magnetic diagnostic system

Author

Peruzzo, Simone, Albanese, Raffaele, Artaserse, Giovanni, Coccorese, Vincenzo, Gerasimov, Sergei, Lam, Norman, Maviglia, Francesco, Pearson, Ian, Prior, Phil, Quercia, Antonio, and Zabeo, Luca

Published

2009

4. Identification of vertical instabilities in the JET Tokamak

Author

Albanese, Raffaele, Artaserse, Giovanni, Maviglia, Francesco, Piccolo, Fabio, and Sartori, Filippo

Subjects

Electromagnetic fields -- Research, Magnetic fields -- Models, Magnetic fields -- Analysis, Business, Electronics, Electronics and electrical industries

Abstract

This paper deals with the electromagnetic aspects related to a series of experiments aimed at the identification and control of vertical instabilities in the JET Tokamak. The first part of the work is devoted to model the transient magnetic fields produced by the poloidal field circuits and the plasma edge localized modes (ELMs). The second part describes the approach used to design an ELM independent plasma speed estimator. The design of the estimator had to be developed with the constraint of using the present controller parameters, so as to minimize the impact on JET operation. Index Terms--Inverse problems, ionized particles, optimization, plasma.

Published

2008

5. Overview of the FTU results

Author

Pucella, Gianluca, Alessi, Edoardo, Amicucci, Luca, Angelini, B, Apicella, Maria, Apruzzese, Gerarda, Artaserse, Giovanni, Belli, Francesco, Bin, William, Boncagni, Luca, Botrugno, Antonio, Briguglio, Sergio, Bruschi, A, and Buratti, Paolo

Subjects

plasma sources, magnetism, electrons, electron multipliers, Cyclotrons, Cyclotrons, electric fields, electric fields

Published

2017

6. Coupling plasmas and 3D passive structures in the JET tokamak

Author

Albanese, Raffaele, primary, Artaserse, Giovanni, additional, Bellizio, Teresa, additional, Rubinacci, Guglielmo, additional, Fresa, Raffaele, additional, Viola, Bruno, additional, Palumbo, Maurizio Furno, additional, Villone, Fabio, additional, Liu, Yueqiang, additional, and Contributors, JET-EFDA, additional

Published

2010

7. Control of Elongated Plasma in Presence of ELMs in the JET Tokamak.

Author

Bellizio, Teresa, Albanese, Raffaele, Ambrosino, Giuseppe, Ariola, Marco, Artaserse, Giovanni, Crisanti, Flavio, Coccorese, Vincenzo, De Tommasi, Gianmaria, Lomas, Peter J., Maviglia, Francesco, Neto, Andre, Pironti, Alfredo, Rimini, Fernanda, Sartori, Filippo, Vitelli, Riccardo, Zabeo, Luca, and JET EFDA Contributors

Subjects

PLASMA confinement, TOKAMAKS, NUCLEAR fusion, TOROIDAL magnetic circuits, PLASMA heating, MAGNETIC fields, PHYSICS projects

Abstract

Tokamaks are the most promising approach for nuclear fusion on earth. They are toroidal machines where the plasma is heated in a ring-shaped vessel and kept away from the vessel by applied magnetic fields. To achieve high performance in tokamaks, plasmas with elongated poloidal cross-section are needed. Such elongated plasmas are vertically unstable, hence position control on a fast time scale is clearly an essential feature for all tokamak devices. In this context the Plasma Control Upgrade project was aimed at increasing the capabilities of the Vertical Stabilization (VS) of the JET tokamak. This paper introduces the new JET VS system and focuses on how the flexibility of this real-time system has been exploited to enlarge its operational limits in terms of maximum controllable disturbance. Eventually, some experimental results achieved during the last experimental campaigns are presented. [ABSTRACT FROM PUBLISHER]

Published

2011

8. Overview of disruptions with JET-ILW

Author

R. Felton, S. Jachmich, C. Stuart, S.N. Gerasimov, U. Kruezi, W. Schippers, G. Szepesi, I. H. Coffey, M. Baruzzo, R.B. Henriques, and Jet Contributors, Ivo S. Carvalho, M. Tsalas, M. Maslov, D. Valcarcel, Peter J. Lomas, Sara Moradi, P. Abreu, E. de la Luna, T. C. Hender, G. Artaserse, P. Buratti, L. Piron, P. McCullen, E. Matveeva, F.G. Rimini, Leonid E. Zakharov, United Kingdom Atomic Energy Authority, Culham Centre for Fusion Energy, Culham Science Centre, Abingdon Oxon, OX14 3DB, United Kingdom of Great Britain and Northern Ireland, Instituto Superior Técnico, Universidade de Lisboa (IST), ENEA-Frascati, RFX, Corso Stati Uniti 4, Padova, Italy, Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas (CIEMAT), EURATOM/UKAEA Fusion Association, Culham Science Centre, Abingdon, Institut méditerranéen d'océanologie (MIO), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Toulon (UTLN)-Centre National de la Recherche Scientifique (CNRS), Charles University, Faculty of Mathematics and Physics, Prague, Czech Republic, Laboratory for Plasma Physics?LPP-ERM/KMS, Royal Military Academy, 1000, Brussels, Belgium, Università degli Studi di Padova = University of Padua (Unipd), Princeton, George Washington University, Gerasimov, S. N., Abreu, P., Artaserse, Giovanni., Baruzzo, M., Buratti, P., Carvalho, I. S., Coffey, I. H., De La Luna, E., Hender, T. C., Henriques, R. B., Felton, R., Jachmich, S., Kruezi, U., Lomas, P. J., Mccullen, P., Maslov, M., Matveeva, E., Moradi, S., Piron, L., Rimini, F. G., Schippers, W., Stuart, C., Szepesi, G., Tsalas, M., Valcarcel, D., and Zakharov, L. E.

Subjects

Physics, Nuclear and High Energy Physics, Jet (fluid), Tokamak, Condensed Matter Physics, 01 natural sciences, disruption, 010305 fluids & plasmas, law.invention, Nuclear physics, JET, law, 0103 physical sciences, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph], 010306 general physics, tokamak

Abstract

International audience; The paper presents an analysis of disruptions occurring during JET-ILW plasma operations covering the period from the start of ILW (ITER-like wall) operation up to completion of JET operation in 2016. The total number of disruptions was 1951 including 466 with deliberately induced disruptions. The average rate of unintended disruptions was 16.1 %, which is significantly above the ITER target at 15 MA. The pre-disruptive plasma parameters are: plasma current Ip = (0.82-3.38) MA, toroidal field BT = (0.98-3.4) T, safety factor q95 = (1.52-9.05), plasma internal inductance li = (0.58-1.86), Greenwald density limit fraction FGWL = (0.04-1.61), with 720 X-point plasma pulses from a subset of 1420 unintended disruption shots. Massive gas injection (MGI) has been routinely used in protection mode both to terminate pulses when the plasma is at risk of disruption and to mitigate against disruption effects. The MGI was mainly triggered by the n = 1 locked mode (LM) amplitude exceeding a threshold or by the disruption itself, namely, either dIp/dt (specifically, a fast drop in Ip) or the toroidal loop voltage exceeding threshold values. For mitigation purposes, only the LM was used as a physics precursor and threshold on the LM signal was used to trigger the MGI prior to disruption. Long lasting LM (? 100 ms) do exist prior to disruption in 75% of cases. However, 10% of non-disruptive pulses have a LM which eventually vanished without disruption. The plasma current quench (CQ) may result in 3D configurations, termed as asymmetrical disruptions, which are accompanied by sideways forces. Unmitigated vertical displacement events (VDEs) generally have significant plasma current toroidal asymmetries. Unmitigated non-VDE disruptions also have large plasma current asymmetries presumably because there is no plasma vertical position control during the CQ and so they too are subject to large vertical displacements. MGI is a reliable tool to mitigate 3D effects and correspondingly sideways forces during the CQ. The vessel structure loads depend on the force impulse and force time behaviour, including their rotation. The toroidal rotation of 3D configuration may cause resonance with the natural frequencies of the vessel components in large tokamaks such as ITER. The JET-ILW amplitude-frequency interdependence of toroidal rotation of 3D configurations is presented.

Published

2020