BEGIN:VCALENDAR
VERSION:2.0
PRODID:icalendar-ruby
CALSCALE:GREGORIAN
METHOD:PUBLISH
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/12421/4597191
DTSTART:20180209T093000Z
DTEND:20180209T110000Z
CLASS:PUBLIC
CREATED:20180109T122236Z
DESCRIPTION: End of 1981 the Electron Cyclotron Heating (ECH) Division in t
 he Institute for Plasma Research (IPF) of the University of Stuttgart was 
 founded with members of the former Belt-Pinch\, Theta-Pinch and “Plasmau
 s” (linear 2.45 GHz RF plasma device) Groups in order to develop a 28 GH
 z\, 0.2 MW\, 40 ms ECH system for plasma start-up\, heating and confinemen
 t experiments on the Wendelstein W7-A Stellarator at IPP Garching. Since t
 hese experiments were very successful\, later 70 GHz and 140 GHz ECH and n
 on-inductive current drive CD systems were installed. This colloquium talk
  will review the first 10 years of ECH&amp\;CD experiments on Wendelstein 
 Stellarators.\nVortragende(r): Prof. M. Thumm (Karlsruhe Institute of Tech
 nology (KIT))
LAST-MODIFIED:20180125T101638Z
LOCATION:IPP Greifswald und Garching\, Raum: HGW S1 (Übertragung Hörsaal 
 D2)
ORGANIZER;CN=IPP:mailto:
SUMMARY:Institutskolloquium: The 1st Decade of Electron Cyclotron Heating E
 xperiments on Wendelstein Stellarators - A (Partially) Humorous Retrospect
  -
URL;VALUE=URI:https://www.ipp.mpg.de/events/12421/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/12996/4597191
DTSTART:20180406T083000Z
DTEND:20180406T100000Z
CLASS:PUBLIC
CREATED:20180222T151037Z
DESCRIPTION:Based on scenario and energy systems modeling\, the talk provid
 es a perspecitve on the requirements and challenges for the future energy 
 system and the role of energy sources such as nuclear\, bio\, solar and wi
 nd and the growth and development of energy carriers such as electricity\,
  hydrogen and hydro-carbons. The talk provides a first principles perspect
 ive on resource costs\, sustainability and reliability and highlights the 
 trade-offs that different energy resources provide. The central role of en
 ergy technology research and innovation is highlighted.\nVortragende(r): D
 r. Chris Laurens
LAST-MODIFIED:20180227T143800Z
LOCATION:IPP Garching und Greifswald\, Raum: Hörsaal D2 (Übertragung nach
  HGW 7.1 und 7.2)
ORGANIZER;CN=IPP:mailto:
SUMMARY:Institutskolloquium: The future of the energy - a systems view
URL;VALUE=URI:https://www.ipp.mpg.de/events/12996/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/13280/4597191
DTSTART:20180420T083000Z
DTEND:20180420T100000Z
CLASS:PUBLIC
CREATED:20180313T123104Z
DESCRIPTION: I will introduce the superconducting electron accelerator ELBE
  (Electron Linear accelerator with high Brilliance and low Emittance) as a
  source for different types of secondary radiation\, including low- (meV) 
 and high- (MeV) energy photons\, positrons and neutrons. Being a solid-sta
 te spectroscopist\, I will then focus on research we have performed using 
 the terahertz free-electron laser FELBE. Here the high peak power can be e
 mployed for nonlinear optical experiments in the THz range\, whereas the p
 icosecond pulse structure enables time-resolved studies of relaxation proc
 esses.\nVortragende(r): Prof. Dr. Manfred Helm
LAST-MODIFIED:20180327T085800Z
LOCATION:Hörsaal D2 (Übertragung nach HGW S1)
SUMMARY:Institutskolloquium:  The multi-purpose electron accelerator ELBE a
 nd its applications\, with a focus on THz spectroscopy
URL;VALUE=URI:https://www.ipp.mpg.de/events/13280/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/13281/4597191
DTSTART:20180427T083000Z
DTEND:20180427T100000Z
CLASS:PUBLIC
CREATED:20180313T123453Z
DESCRIPTION:The LHCb detector at the Large Hadron Collider has been optimis
 ed for the study of rare decays of heavy flavour particles and the breakin
 g of the symmetry between matter and antimatter. After a general introduct
 ion to the experiment\, the talk will focus on the most important results 
 obtained so far and their relevance for the search of physics beyond the S
 tandard Model.\nVortragende(r):  Prof. Dr. Michael Schmelling
LAST-MODIFIED:20180425T071621Z
LOCATION:Garching und Greifswald\, Raum: Hörsaal D2 (Übertragung nach HGW
  S2)
SUMMARY:Institutskolloquium: Physics Highlights from the LHCb Experiment
URL;VALUE=URI:https://www.ipp.mpg.de/events/13281/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/13284/4597191
DTSTART:20180504T083000Z
DTEND:20180504T100000Z
CLASS:PUBLIC
CREATED:20180313T132857Z
DESCRIPTION:Neutron stars are born as the endpoint of stellar evolution in 
 core-collapse supernovae. The densities in a neutron star are extremely hi
 gh\, so high that nuclei are squeezed into their constituents\, neutrons a
 nd protons. Exotic matter can appear in the core\, either in the form of h
 yperons or as a new phase in the form of strange quark matter. The propert
 ies of neutron stars are determined by the nuclear equation of state of de
 nse matter\, so that the observation of neutron stars and neutron star mer
 ger can give a telltale signature of the properties of dense matter under 
 extreme conditions. The present astrophysical data on neutron stars and pu
 lsars\, rotation-powered neutron stars\, is reviewed. The equation of stat
 e of dense matter will be discussed and possible implications for future o
 bservations of core-collapse supernovae and neutron star mergers will be o
 utlined.\nVortragende(r): Prof. Dr. Jürgen Schaffner-Bielich
LAST-MODIFIED:20180611T104317Z
LOCATION:Garching und Greifswald\, Raum: Hörsaal D2 (Übertragung nach HGW
  S1)
SUMMARY:Institutskolloquium: Dense matter in neutron stars
URL;VALUE=URI:https://www.ipp.mpg.de/events/13284/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/13285/4597191
DTSTART:20180525T083000Z
DTEND:20180525T100000Z
CLASS:PUBLIC
CREATED:20180313T133025Z
DESCRIPTION:The last Nobel Prize in economics was awarded to Richard Thaler
  for his contributions to Behavioral Economics. Behavioral Economics chall
 enges the standard\, neoclassical assumption that economic decision makers
  are fully rational and only concerned about their own material well-being
 . Over the last decades new models of human behavior have been developed\,
  often inspired and tested by fascinating economic experiments. In this le
 cture I will focus on "social preferences"\, a subfield of behavioral econ
 omics to which Thaler and many other economists and psychologists contribu
 ted. It seems obvious that many people are not only motivated by their own
  material well-being but often care about other people. Altruism\, spite\,
  inequality aversion\, concerns for fairness and reciprocal behavior have 
 an important impact on economic decision making. However\, it is often dif
 ficult to disentangle the exact motivations that are driving economic beha
 vior. In this lecture I will give a brief introduction into this field and
  discuss some recent experiments on the dark side of social preferences.\n
 Vortragende(r): Prof. Klaus Schmidt
LAST-MODIFIED:20180516T153140Z
LOCATION:Hörsaal D2 (Übertragung nach HGW S1)
SUMMARY:Institutskolloquium: Homo Oeconomicus or Homo Reciprocans?
URL;VALUE=URI:https://www.ipp.mpg.de/events/13285/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/13286/4597191
DTSTART:20180608T083000Z
DTEND:20180608T100000Z
CLASS:PUBLIC
CREATED:20180313T133159Z
DESCRIPTION: The idea for a new kind of optical glass fibre—photonic crys
 tal fibre (PCF)—first emerged in 1991. The aim was to realise a fibre wi
 th a two-dimensional periodic array of microscopic features (typically hol
 low channels) running along its entire length. These would be able to corr
 al light within a central hollow or solid core\, permitting light and matt
 er waves to be tightly confined over long distances while precisely contro
 lling the dispersion. More than a quarter of a century later\, PCF has led
  to a whole series of new developments\, some of which are already are mov
 ing into real-world applications. Solid-core PCFs are routinely used to tr
 ansform invisible infrared laser pulses into white light 10 million times 
 brighter than an arc lamp\, and form the basis of commercial supercontinuu
 m sources. Twisted PCF creates optical vortices that carry orbital angular
  momentum\, as well as providing an elegant means of providing circular bi
 refringence and dichroism. Intense interactions between light and sound in
  solid-core PCF enable stable all-optical mode-locking of fibre lasers at 
 a high harmonic (a few GHz) of their round-trip frequency. Single-ring hol
 low-core PCF\, comprising a ring of thin-walled capillaries surrounding a 
 central hollow core\, guides over an extremely wide frequency range and\, 
 through pressure-adjustable dispersion\, provides a simple means of compre
 ssing pulses down to single-cycle durations\, as well as underpinning a ra
 nge of unique and extremely bright sources of tunable deep and vacuum ultr
 aviolet light.\nVortragende(r): Prof. Philip Russell
LAST-MODIFIED:20180528T132826Z
LOCATION:Hörsaal D2 (Übertragung nach HGW S1)
SUMMARY:Institutskolloquium: Gas\, glass &amp\; light: 25+ years of photoni
 c crystal fibres
URL;VALUE=URI:https://www.ipp.mpg.de/events/13286/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/14141/4597191
DTSTART:20180622T083000Z
DTEND:20180622T100000Z
CLASS:PUBLIC
CREATED:20180517T145907Z
DESCRIPTION:Due to the presence of multiple physical scales and complex non
 linear interactions\, the numerical simulation of fusion plasmas often lea
 ds to computational problems of huge complexity. A long-standing challenge
  is then to design numerical methods that are computationally efficient\, 
 high order accurate and stable on very long time scales. Fortunately\, ste
 ady progresses in the theory of structure-preserving discretizations have 
 provided a solid mathematical ground for the development of stable high or
 der numerical schemes. In this lecture I will give a brief review of the c
 ompatible Finite Element methods that have been developed in this directio
 n\, and I will explain how these tools are now being extended to design st
 able numerical models for the Vlasov-Maxwell equations. Recent ideas that 
 allow to further improve the computational efficiency of such methods will
  be presented\, along with a novel approach to low-noise particle approxim
 ations.\nVortragende(r): Dr. Martin Campos Pinto
LAST-MODIFIED:20180528T133332Z
LOCATION:Garching und Greifswald\, Raum: Hörsaal D2 (Übertragung nach HGW
  S1)
ORGANIZER;CN=IPP:mailto:
SUMMARY:Institutskolloquium: New approaches to stable models for computatio
 nal plasma physics
URL;VALUE=URI:https://www.ipp.mpg.de/events/14141/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/13868/4597191
DTSTART:20180629T083000Z
DTEND:20180629T100000Z
CLASS:PUBLIC
CREATED:20180424T161412Z
DESCRIPTION:Comparing North Korea's achievements in the field of missiles w
 ith the programs of other countries\, one gets the impression that North K
 orea is a nation of rocket scientists. The recent glorious successes appea
 r like a deja vu of the early days of North Korea's missile program in the
  1980s and 1990s\, when the country managed to present a full missile prog
 ram out of the blue. But a close look from an engineer's perspective revea
 ls some discrepancies in the common narrative\, thus allowing for some sur
 prising insights into the current situation of North Korea's missile threa
 t.\nVortragende(r): Dr.-Ing. Markus Schiller
LAST-MODIFIED:20180619T120438Z
LOCATION:Garching und Greifswald\, Raum: Hörsaal D2 (Übertragung nach HGW
  S1)
ORGANIZER;CN=IPP:mailto:
SUMMARY:Institutskolloquium: From the beginnings to the (preliminary?) end 
 of the North Korean missile program
URL;VALUE=URI:https://www.ipp.mpg.de/events/13868/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/14047/4597191
DTSTART:20180713T083000Z
DTEND:20180713T100000Z
CLASS:PUBLIC
CREATED:20180508T111211Z
DESCRIPTION: The European Spallation Source (ESS)\, which is currently unde
 r construction in Lund\, Sweden\, is designed to push the limits of resear
 ch with neutrons to new horizons. ESS will open up new scientific opportun
 ities which are complementary to those at X-ray sources. These will includ
 e unprecedented in-situ and in-operando experiments which are only possibl
 e with neutrons due to their special properties. After a short summary of 
 the design and the specifications of the European Spallation Source an ove
 rview of the current status and schedule of the ESS construction project w
 ill be given with a strong focus on the instruments and the surrounding sc
 ientific infrastructure. The overall goal of ESS is to begin user operatio
 n in 2023 and ramp up to 15 instruments by 2026. Selected examples of new 
 scientific opportunities in the field of materials and life science will b
 e discussed.\nVortragende(r): Prof. Dr. Andreas Schreyer
LAST-MODIFIED:20181214T090319Z
LOCATION:Garching und Greifswald\, Raum: Hörsaal D2 (Übertragung nach HGW
  S1)
ORGANIZER;CN=IPP:mailto:
SUMMARY:Institutskolloquium: The European Spallation Source: New Opportunit
 ies for Science 
URL;VALUE=URI:https://www.ipp.mpg.de/events/14047/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/13825/4597191
DTSTART:20180914T083000Z
DTEND:20180914T100000Z
CLASS:PUBLIC
CREATED:20180419T114447Z
DESCRIPTION:Max Planck wurde in einem Akt der Verzweiflung zum Revolutionä
 r seines Fachs und zum Begründer der modernen Physik. Mit seiner Quantent
 heorie zerbrach das bis dahin stabile wissenschaftliche Bild der Welt. Der
  Vortrag porträtiert den Physiker und Menschen Max Planck\, in dessen Wer
 k und Leben sich Triumph und Tragik vereinen. Dabei entsteht das Bild eine
 r ganzen Epoche\, die historisch\, wissenschaftlich und philosophisch den 
 Aufbruch in die Moderne darstellt.\nVortragende(r): Prof. Dr. Ernst Peter 
 Fischer
LAST-MODIFIED:20180910T083158Z
LOCATION:Hörsaal D2\, Seminarraum ITED/I-Gebäude (Übertragung nach HGW S
 2)
SUMMARY:Institutskolloquium: Wo landet man nach einem Quantensprung? – Vo
 rtrag aus Anlass des bundesweiten Max-Planck-Tags
URL;VALUE=URI:https://www.ipp.mpg.de/events/13825/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/13288/4597191
DTSTART:20180928T083000Z
DTEND:20180928T100000Z
CLASS:PUBLIC
CREATED:20180313T133509Z
DESCRIPTION: Precision spectroscopy is a driving force for the development 
 of our physical understanding. However\, only few atomic and molecular sys
 tems of interest have been accessible for precision spectroscopy in the pa
 st\, since they miss a suitable transition for laser cooling and internal 
 state detection. This restriction can be overcome in trapped ions through 
 quantum logic spectroscopy. Coherent laser manipulation originally develop
 ed in the context of quantum information processing with trapped ions allo
 ws us to combine the special spectroscopic properties of one ion species (
 spectroscopy ion) with the excellent control over another species (logic o
 r cooling ion). The logic ion provides sympathetic cooling and is used to 
 control and read out the internal state of the spectroscopy ion. In my pre
 sentation I will provide an overview of different implementations of quant
 um logic spectroscopy suitable for narrow (long-lived) and broad (dipole-a
 llowed) transitions. Applications range from highly accurate optical clock
 s based on aluminium ions\, over precision spectroscopy of broad and non-c
 losed transitions in calcium isotopes\, to non-destructive internal state 
 detection and spectroscopy of molecular ions. Prospects to extend quantum 
 logic spectroscopy to highly charged ions and first steps towards this goa
 l will be discussed.Spectroscopy of these species enables a multitude of t
 ests for physics beyond the Standard Model\, such as probing for new force
  carriers and scalar fields that are dark matter candidates and could indu
 ce a variation of fundamental constants. Measurements of isotope shifts of
  narrow transitions in calcium isotopes probes nuclear structure and may a
 llow to constrain new forces coupling electrons and neutrons. Precision sp
 ectroscopy of e.g. vibrational transitions in molecular ions will allow to
  put bounds on a possible variation of the electron-to-proton mass ratio\,
  while highly charged ions are among the most sensitive systems to probe f
 or a variation of the fine-structure constant.Picture: Sympathetically coo
 led highly-charged ions. Left: Ar<sup>13+</sup> in a cloud of laser-cooled
  Be<sup>+</sup> ions. Right: Two Be<sup>+</sup> ions separated by a single
  Ar<sup>13+</sup> ion.\nVortragende(r):  Prof. Piet Schmidt
LAST-MODIFIED:20180821T092416Z
LOCATION:Hörsaal D2 (Übertragung nach HGW S1)
SUMMARY:Institutskolloquium:  Quantum Logic Spectroscopy of Trapped Ions 
URL;VALUE=URI:https://www.ipp.mpg.de/events/13288/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/13289/4597191
DTSTART:20181012T083000Z
DTEND:20181012T100000Z
CLASS:PUBLIC
CREATED:20180313T133648Z
DESCRIPTION:A profound understanding of turbulence in fusion plasmas is par
 amount because of its strong impact on both core and edge plasma transport
 . Turbulence is a key player in determining particle\, energy\, and moment
 um fluxes and thus dictates the shape of the density\, temperature\, and r
 otation profiles\, which set the the efficiency of a fusion reactor. Gyrok
 inetic theory is considered nowadays to be the state of the art when it co
 mes to a compromise between realism and efficiency\, but must be validated
  to improve the reliability of predicting profiles for future fusion devic
 es. The fundamentals of turbulence\, its generation and its characterizati
 on with both measurements and simulations will be presented. For the core 
 plasma\, particular attention is paid to the comparison between measuremen
 ts and gyrokinetic simulations\, which has led to significant gains in und
 erstanding. The edge turbulence behavior in different confinement regimes 
 is contrasted. Strong turbulence is usually observed in the L-mode edge wh
 ile the H-mode edge plasma exhibits a reduced turbulence level. In yet ano
 ther confinement regime\, the improved energy confinement mode (I-mode)\, 
 edge turbulence is reduced to a large degree. However\, strongly intermitt
 ent high amplitude events are observed. An analytic candidate generation m
 echanisms is presented and first results from accompanying gyrokinetic sim
 ulations of the I-mode edge – consistent with the observations – are r
 eported.\nVortragende(r): Dr. Tim Happel
LAST-MODIFIED:20180925T110349Z
LOCATION:Hörsaal D2 (Übertragung nach HGW S1)
SUMMARY:Institutskolloquium: Exploring Turbulence in Fusion Plasmas through
  Experiment and Simulation
URL;VALUE=URI:https://www.ipp.mpg.de/events/13289/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/15100/4597191
DTSTART:20181026T083000Z
DTEND:20181026T100000Z
CLASS:PUBLIC
CREATED:20180820T135109Z
DESCRIPTION:Despite the progress made at the Paris climate talks with respe
 ct to reducing emissions of greenhouse gases it is possible that the rate 
 of environmental change may result in extensive negative impacts for human
 s and natural ecosystems. Clearly\, emissions cuts are essential to managi
 ng climate risk and reducing climate change. However\, given the potential
  consequences of a high rate of environmental change\, it is important to 
 investigate complementary approaches. For example\, geoengineering methods
  aimed at altering earth's radiation budget may offer a fast-acting way of
  moderating the rate of climate change. However\, such geoengineering appr
 oaches entail a number of new risks\, and cannot replace reducing CO<sub>2
 </sub> emissions/levels. I will discuss different geoengineering methods\,
  focusing on new approaches to stratospheric solar radiation management\, 
 highlighting technical capabilities and risk. I will also briefly discuss 
 questions surrounding the potential implementation of such approaches.\nVo
 rtragende(r): Prof. Frank N. Keutsch
LAST-MODIFIED:20181214T090409Z
LOCATION:Garching und Greifswald\, Raum: Seminarraum L6\, 2. Stock Süd (Ü
 bertragung nach HGW S1)
ORGANIZER;CN=IPP:mailto:
SUMMARY:Institutskolloquium:  Solar geoengineering - taking the edge off cl
 imate change? 
URL;VALUE=URI:https://www.ipp.mpg.de/events/15100/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/15863/4597191
DTSTART:20181116T093000Z
CLASS:PUBLIC
CREATED:20181024T075221Z
DESCRIPTION:The brain routinely discovers sensory clues that predict opport
 unities or dangers. However\, it is unclear how neural learning processes 
 can bridge the typically long delays between sensory clues and behavioral 
 outcomes. Here\, I introduce a learning concept\, aggregate-label learning
 \, that enables biologically plausible model neurons to solve this tempora
 l credit assignment problem. Aggregate-label learning matches a neuron’s
  number of output spikes to a feedback signal that is proportional to the 
 number of clues but carries no information about their timing. Aggregate-l
 abel learning outperforms stochastic reinforcement learning at identifying
  predictive clues and is able to solve unsegmented speech-recognition task
 s. Furthermore\, it allows unsupervised neural networks to discover reoccu
 rring constellations of sensory features even when they are widely dispers
 ed across space and time.\nVortragende(r): Prof. Robert Gütig
LAST-MODIFIED:20181024T080250Z
LOCATION:Garching und Greifswald\, Raum: HGW S1 (Übertragung Hörsaal D2)
ORGANIZER;CN=IPP:mailto:
SUMMARY:Institutskolloquium: Learning across space and time in spiking neur
 al networks
URL;VALUE=URI:https://www.ipp.mpg.de/events/15863/4597191
END:VEVENT
BEGIN:VEVENT
DTSTAMP:20260518T162614Z
UID:https://www.ipp.mpg.de/events/16127/4597191
DTSTART:20181207T093000Z
DTEND:20181207T110000Z
CLASS:PUBLIC
CREATED:20181116T141813Z
DESCRIPTION:Large-scale plasma instabilities with the potential of damaging
  wall structures or reducing their lifetime are a significant concern for 
 magnetic confinement fusion. Among the most critical are disruptions and e
 dge localized modes. Predicting the behavior of such instabilities and the
 ir control for ITER and beyond is a challenging task for which input from 
 experiments\, theory\, and simulations is needed. This presentation descri
 bes non-linear MHD simulations of edge localized modes\, disruptions and c
 ontrol strategies. The talk will explain why simulations or large-scale in
 stabilities are needed and show that our simulations have already revealed
  a lot of aspects about the physics of large-scale instabilities. It will 
 also give some insights into the actual work involved “behind the scenes
 ” and challenges we are facing for the future.\nVortragende(r): Dr. Matt
 hias Hoelzl
LAST-MODIFIED:20181116T141819Z
LOCATION:Garching und Greifswald\, Raum: Hörsaal D2 (Übertragung nach HGW
  S1)
ORGANIZER;CN=IPP:mailto:
SUMMARY:Institutskolloquium: Edge localized modes and disruptions – Insig
 hts into large-scale plasma instabilities from non-linear magneto-hydrodyn
 amic simulations
URL;VALUE=URI:https://www.ipp.mpg.de/events/16127/4597191
END:VEVENT
END:VCALENDAR