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@article{lorenzini2009self,
title={Self-organized helical equilibria as a new paradigm for ohmically heated fusion plasmas},
author={Lorenzini, Rita and Martines, E and Piovesan, P and Terranova, D and Zanca, P and Zuin, M and Alfier, A and Bonfiglio, D and Bonomo, F and Canton, A and others},
journal={Nature Physics},
volume={5},
number={8},
pages={570--574},
year={2009},
publisher={Nature Publishing Group UK London}
}
@article{escande2000single,
title={Single helicity: a new paradigm for the reversed field pinch},
author={Escande, DF and Cappello, S and D'Angelo, F and Martin, Piero and Ortolani, S and Paccagnella, R},
journal={Plasma Physics and Controlled Fusion},
volume={42},
number={12B},
pages={B243},
year={2000},
publisher={IOP Publishing}
}
@misc{ipfsContentAddressing,
author = {{IPFS Project}},
title = {Content Addressing},
howpublished = {\url{https://docs.ipfs.tech/concepts/content-addressing/}},
note = {Accessed: 2025-06-14}
}
@article{bhat2022understanding,
title={Understanding docker compose},
author={Bhat, Sathyajith and Bhat, Sathyajith},
journal={Practical Docker with Python: Build, Release, and Distribute Your Python App with Docker},
pages={165--198},
year={2022},
publisher={Springer}
}
@misc{sqlalchemyPhilosophy,
author = {{SQLAlchemy}},
title = {SQLAlchemy Philosophy},
url = {https://www.sqlalchemy.org/philosophy.html},
note = {Accessed: 2025-06-14}
}
@article{gardner2009web,
title={The web server gateway interface (wsgi)},
author={Gardner, James},
journal={The Definitive Guide to Pylons},
pages={369--388},
year={2009},
publisher={Springer}
}
@book{karim2017scala,
title={Scala and Spark for Big Data Analytics: Explore the concepts of functional programming, data streaming, and machine learning},
author={Karim, Md Rezaul and Alla, Sridhar},
year={2017},
publisher={Packt Publishing Ltd}
}
@book{white2012hadoop,
title={Hadoop: The definitive guide},
author={White, Tom},
year={2012},
publisher={" O'Reilly Media, Inc."}
}
@article{stillerman1997mdsplus,
title={MDSplus data acquisition system},
author={Stillerman, JA and Fredian, TW and Klare, KA and Manduchi, G},
journal={Review of Scientific Instruments},
volume={68},
number={1},
pages={939--942},
year={1997},
publisher={American Institute of Physics}
}
@misc{materialdesign,
author = "Google",
title = "Google's Material Design",
year = 2024,
url = "https://m3.material.io/get-started",
note = {Accessed: 2025-06-12}
}
@book{flanagan2011javascript,
title={JavaScript: the definitive guide},
author={Flanagan, David},
year={2011},
publisher={" O'Reilly Media, Inc."}
}
@phdthesis{Fielding2000,
author = {Roy Thomas Fielding},
title = {Architectural Styles and the Design of Network-based Software Architectures},
school = {University of California, Irvine},
year = {2000},
type = {Ph.D. Dissertation},
url = {https://ics.uci.edu/~fielding/pubs/dissertation/top.htm},
note = {Accessed: 2025-06-12}
}
@article{ireland2009understanding,
title={Understanding object-relational mapping: A framework based approach},
author={Ireland, Christopher and Bowers, David and Newton, Michael and Waugh, Kevin},
journal={International lournal On Advances in Software},
volume={2},
number={2},
year={2009},
publisher={Citeseer}
}
@misc{Pike2012,
author = {Rob Pike},
title = {Go at Google: Language Design in the Service of Software Engineering},
howpublished = {\url{https://go.dev/talks/2012/splash.article}},
note = {Accessed: 2025-06-12}
}
@manual{postgresqldocs,
title = {PostgreSQL Documentation},
author = {{The PostgreSQL Global Development Group}},
url = {https://www.postgresql.org/docs/}
}
@book{tokamaks,
author = {John Wesson and D. J. Campbell},
title = {Tokamaks},
publisher = {Oxford University Press},
year = {2011}
}
@book{plasma-physics-and-fusion-energy,
author = {Jeffrey P. Freidberg},
title = {Plasma Physics and Fusion Energy},
publisher = {Cambridge University Press},
year = {2007}
}
@article{the-reversed-field-pinch,
author = {L. Marrelli and others},
title = {The reversed field pinch},
journal = {Nuclear Fusion},
volume = {61},
year = {2021},
}
@article{topical-issue-rfx,
author = {G. Rostagni and others},
title = {Topical Issue on the RFX-experiment, Padova},
journal = {Fusion Engineering and Design},
volume = {25},
pages = {301--504},
year = {1995},
}
@book{cecco,
title = "Experimental studies of confinement in the EXTRAP T2 and T2R reversed field pinches",
author = "M. Cecconello",
publisher = "Alfvén Laboratory, Fusion Plasma Physics, Royal Institute of Technology, Stockholm",
year = "2003"
}
@book{wesson,
title = "Tokamaks",
author = "J. Wesson",
publisher = "Claredon Press",
year = "1987"
}
@techreport{rfc6749,
author = {D. Hardt, Ed.},
title = {The OAuth 2.0 Authorization Framework},
institution = {Internet Engineering Task Force},
type = {RFC},
number = {6749},
year = {2012},
month = {October},
url = {https://datatracker.ietf.org/doc/html/rfc6749},
}
@techreport{rfc7636,
author = {N. Sakimura, Ed and J. Bradley and N. Agarwal},
title = {{Proof Key for Code Exchange by OAuth Public Clients}},
institution = {Internet Engineering Task Force},
type = {RFC},
number = {7636},
year = {2015},
month = {September},
url = {https://www.rfc-editor.org/rfc/rfc7636.html},
}
@book{spark-in-action,
author = {Petar Zečević and Marko Bonaći},
title = {Spark in Action},
publisher = {Manning},
year = {2016}
}
@book{learning-spark,
author = {Jules S. Damji and Brooke Wenig and Tathagata Das and Denny Lee},
title = {Learning Spark: Lightning-Fast Data Analytics},
publisher = {O'Reilly Media},
year = {2020}
}
@book{wesson2004tokamaks,
title={Tokamaks},
author={Wesson, J. and Campbell, D.J.},
isbn={9780198509226},
lccn={2004266929},
series={International series of monographs on physics},
url={https://books.google.it/books?id=iPlAwZI6HIYC},
year={2004},
publisher={Clarendon Press}
}
@article{Puiatti_2015,
doi = {10.1088/0029-5515/55/10/104012},
url = {https://dx.doi.org/10.1088/0029-5515/55/10/104012},
year = {2015},
month = {jul},
publisher = {IOP Publishing},
volume = {55},
number = {10},
pages = {104012},
author = {Puiatti, M.E. and Dal Bello, S. and Marrelli, L. and Martin, P. and Agostinetti, P. and Agostini, M. and Antoni, V. and Auriemma, F. and Barbisan, M. and Barbui, T. and Baruzzo, M. and Battistella, M. and Belli, F. and Bettini, P. and Bigi, M. and Bilel, R. and Boldrin, M. and Bolzonella, T. and Bonfiglio, D. and Brombin, M. and Buffa, A. and Canton, A. and Cappello, S. and Carraro, L. and Cavazzana, R. and Cester, D. and Chacon, L. and Chapman, B.E. and Chitarin, G. and Ciaccio, G. and Cooper, W.A. and Dalla Palma, M. and Deambrosis, S. and Delogu, R. and De Lorenzi, A. and De Masi, G. and Dong, J.Q. and Escande, D.F. and Esposito, B. and Fassina, A. and Fellin, F and Ferro, A. and Finotti, C. and Franz, P. and Frassinetti, L. and Furno Palumbo, M. and Gaio, E. and Ghezzi, F. and Giudicotti, L. and Gnesotto, F. and Gobbin, M. and Gonzales, W.A. and Grando, L. and Guo, S.C. and Hanson, J.D. and Hirshman, S.P. and Innocente, P. and Jackson, J.L. and Kiyama, S. and Komm, M. and Laguardia, L. and Li, C. and Liu, S.F. and Liu, Y.Q. and Lorenzini, R. and Luce, T.C. and Luchetta, A. and Maistrello, A. and Manduchi, G. and Mansfield, D.K. and Marchiori, G. and Marconato, N. and Marocco, D. and Marcuzzi, D. and Martines, E. and Martini, S. and Matsunaga, G. and Mazzitelli, G. and Miorin, E. and Momo, B. and Moresco, M. and Okabayashi, M. and Olofsson, E. and Paccagnella, R. and Patel, N. and Pavei, M. and Peruzzo, S. and Pilan, N. and Pigatto, L. and Piovan, R. and Piovesan, P. and Piron, C. and Piron, L. and Predebon, I. and Rea, C. and Recchia, M. and Rigato, V. and Rizzolo, A. and Roquemore, A.L. and Rostagni, G. and Ruset, C and Ruzzon, A. and Sajò-Bohus, L. and Sakakita, H. and Sanchez, R. and Sarff, J.S. and Sartori, E. and Sattin, F. and Scaggion, A. and Scarin, P. and Schmitz, O. and Sonato, P. and Spada, E. and Spagnolo, S. and Spolaore, M. and Spong, D.A. and Spizzo, G. and Stevanato, L. and Takechi, M. and Taliercio, C. and Terranova, D. and Trevisan, G.L. and Urso, G. and Valente, M. and Valisa, M. and Veranda, M. and Vianello, N. and Viesti, G. and Villone, F. and Vincenzi, P. and Visona', N. and Wang, Z.R. and White, R.B. and Xanthopoulos, P. and Xu, X.Y. and Yanovskiy, V. and Zamengo, A. and Zanca, P. and Zaniol, B. and Zanotto, L. and Zilli, E. and Zuin, M.},
title = {Overview of the RFX-mod contribution to the international Fusion Science Program},
journal = {Nuclear Fusion},
abstract = {The RFX-mod device is operated both as a reversed field pinch (RFP), where advanced regimes featuring helical shape develop, and as a tokamak. Due to its flexibility, RFX-mod is contributing to the solution of key issues in the roadmap to ITER and DEMO, including MHD instability control, internal transport barriers, edge transport and turbulence, isotopic effect, high density limit and three-dimensional (3D) non-linear MHD modelling. This paper reports recent advancements in the understanding of the self-organized helical states, featuring a strong electron transport barrier, in the RFP configuration; the physical mechanism driving the residual transport at the barrier has been investigated. Following the first experiments with deuterium as the filling gas, new results concerning the isotope effect in the RFP are discussed. Studies on the high density limit show that in the RFP it is related to a toroidal particle accumulation due to the onset of a convective cell. In the tokamak configuration, q(a) regimes down to q(a) = 1.2 have been pioneered, with (2,1) tearing mode (TM) mitigated and (2,1) resistive wall mode (RWM) stabilized: the control of such modes can be obtained both by poloidal and radial sensors. Progress has been made in the avoidance of disruptions due to the (2,1) TM by applying q(a) control, and on the general issue of error field control. The effect of externally applied 3D fields on plasma flow and edge turbulence, sawtooth control and runaway electron decorrelation has been analysed. The experimental program is supported by substantial theoretical activity: 3D non-linear visco-resistive MHD and non-local transport modelling have been advanced; RWMs have been studied by a toroidal MHD kinetic hybrid stability code.}
}
@article{Martin_Greenwald_2002,
doi = {10.1088/0741-3335/44/8/201},
url = {https://dx.doi.org/10.1088/0741-3335/44/8/201},
year = {2002},
month = {jul},
publisher = {},
volume = {44},
number = {8},
pages = {R27},
author = {Martin Greenwald},
title = {Density limits in toroidal plasmas},
journal = {Plasma Physics and Controlled Fusion},
abstract = {In addition to the operational limits imposed by MHD stability on plasma current and pressure, an independent limit on plasma density is observed in confined toroidal plasmas. This review attempts to summarize recent work on the phenomenology and physics of the density limit. Perhaps the most surprising result is that all of the toroidal confinement devices considered operate in similar ranges of (suitably normalized) densities. The empirical scalings derived independently for tokamaks and reversed-field pinches are essentially identical, while stellarators appear to operate at somewhat higher densities with a different scaling. Dedicated density limit experiments have not been carried out for spheromaks and field-reversed configurations, however, `optimized' discharges in these devices are also well characterized by the same empirical law. In tokamaks, where the most extensive studies have been conducted, there is strong evidence linking the limit to physics near the plasma boundary: thus, it is possible to extend the operational range for line-averaged density by operating with peaked density profiles. Additional particles in the plasma core apparently have no effect on density limit physics. While there is no widely accepted, first principles model for the density limit, research in this area has focussed on mechanisms which lead to strong edge cooling. Theoretical work has concentrated on the consequences of increased impurity radiation which may dominate power balance at high densities and low temperatures. These theories are not entirely satisfactory as they require assumptions about edge transport and make predictions for power and impurity scaling that may not be consistent with experimental results. A separate thread of research looks for the cause in collisionality enhanced turbulent transport. While there is experimental and theoretical support for this approach, understanding of the underlying mechanisms is only at a rudimentary stage and no predictive capability is yet available.}
}