Original Welcome:
This event is dedicated to assembling experts on the fields of plasma and particle physics, in particular on laser induced fusion and particle production in intense fields. These research areas are promising for future development, they connect to the use of large scale international facilities, like CERN and ELI.
Main Topics:
Keynote speakers
Confirmed invited Speakers
International Advisory Committee
Local Organizing Committee (Wigner RCP)
Important Deadlines
Conference Fee
A nucleus having 4n number of nucleons, such as Be, C, O, etc., is theorised to possess
clusters of α particles (He nucleus). The Oxygen nucleus (O) has a double magic number, where the presence of an α-clustered nuclear structure grants additional nuclear stability. In this study, we exploit the anisotropic flow coefficients to discern the effects of an α clustered nuclear geometry w.r.t. a Woods-Saxon nuclear distribution in O–O collisions at √sNN = 7 TeV.
We show that results for the thermodynamics of strongly interacting matter obtained by state of the
art Monte-Carlo simulations of lattice QCD can be adequately described within a generalized BethUhlenbeck type approach, where the hadron resonance gas (HRG) phase appears as a mixture of
(multi-) quark clusters. The underlying chiral quark dynamics is coupled to a background gluon
field using the Polyakov gauge. The transition to the quark-gluon plasma (QGP) phase appears as a
Mott dissociation of the quark clusters described by a model for hadron phase shifts that encodes
the dissociation of bound states in the continuum of scattering states triggered by the chiral
symmetry restoration transition. An important ingredient are Polyakov-loop generalized distribution
functions of multi-quark clusters which are derived here for the first time [1].
This new approach gives a quantitative understanding for the observation of ultrarelativistic heavyion collision that the abundances of hadrons produced in these experiments are well described by a
statistical model within a sudden chemical freeze-out at a well-defined hadronization temperature
despite the fact that the melting of the chiral condensate proceeds as a smooth crossover.
We report for the first time the remarkable finding that the ratio of generalized baryon number
susceptibilities $R_{42}^B(T)=\chi_4^B (T)/\chi_2^B (T)$, which interpolates between the value
$R_{42}^B(T\simeq 140 {\rm MeV})=1$ for a pure HRG and
$R_{42}^B(T>250 {\rm MeV}) \sim1/9 $ for the QGP shall not be mistaken for a measure of the
fraction of hadrons in the system. Its deviation from unity can actually quantify the degree of
overlap of quark wave functions which leads to the quark Pauli blocking effect in the HRG which
leads to repulsive residual interactions which we model by a temperature dependent excluded
baryon volume.
[1] D. Blaschke, M. Cierniak, O. Ivanytskyi and G. Röpke, Eur. Phys. J. A 60 (2024)
[2] D. Blaschke, O. Ivanytskyi and G. Röpke, in preparation
The Large Hadron Collider (LHC) at CERN is the most powerful particle accelerator made by human kind.
With a global collaboration of over 1000 scientists from 40 nations, ALICE delves into the extreme conditions generated by ultrarelativistic collisions of heavy nuclei, reminiscent of the universe mere microseconds after the Big Bang.
This presentation provides a glimpse into the cutting-edge technology ALICE uses to detect and identify subatomic particles created in these collisions. The resulting huge amounts of data require innovative solutions with state-of-the-art computers and algorithms. Some selected physics highlights are presented. An outlook for ALICE for the 2030s is given.
Jet substructure measurements are a powerful tool that probe the parton shower differentially in regions of the QCD radiation phase space. They allow us to study the fragmentation patterns of parton showers in proton-proton collisions as well as their modification by the quark-gluon plasma (QGP) in heavy-ion collisions. Jet substructure can also be used to search for QGP-like modifications in small collision systems. The ALICE experiment has a high-precision tracking system allowing for jet measurements down to low transverse momenta, which makes it important for jet substructure measurements in this regime.
In this presentation, we report several recent jet substructure results in both minimum bias and high multiplicity proton-proton collisions, as well as in Pb–Pb collisions by the ALICE Collaboration. These will include the fully corrected inclusive measurements of the shared momentum fraction of first groomed splitting and the groomed jet radius, as well as measurement of jet axis differences and generalized jet angularities. We also report the measurement of inclusive and leading subjet fragmentation. By mitigating the effects of the underlying event and hadronization processes, these measurements can be compared to theoretical calculations to provide new constraints on the physics that underpin parton fragmentation and jet quenching.
We deepen the understanding of the primordial composition of the Universe in the temperature range $130\,\mathrm{GeV}>T>0.02\,\mathrm{MeV}$ within the Big Bang model. Massive elementary particles: $t,b,c$-quarks, $\tau,\mu$-leptons, and $W, Z$-gauge bosons emerged at about $T=130\,\mathrm{GeV}$. These elementary particles in the following were abundantly present as the Universe expanded and cooled - our interest is to search for periods of possible chemical non-equilibrium of great importance in baryogenesis. Once the temperature dropped below $T=150$\,~MeV quarks and gluons hadronize into matter. We follow the Universe evolution in depth and study near $T=\mathcal{O}(2)$\,~MeV the emergence of the free-streaming neutrino era and develop methods to understand speed of the Universe expansion. We subsequently follow the early universe pass through the hot dense electron-positron plasma epoch and we analyze the paramagnetic characteristics of the electron-positron plasma when exposed to an external primordial magnetic field. The high density of positron antimatter persisted into the Big Bang Nucleosynthesis era which thus requires study of nuclear reactions in the presence of a highly mobile plasma phase, a topic of the following lecture by Chris.
The surge of AI presents an enormous step in the human history. The reaches of that development require constant supervision of the governements because letting the the development in the hands of comercia companies may bring more harm than benefit.
I will discuss some of steps needed to get controle of the developments.
Crater experiments in laser research play a crucial role in advancing our understanding of laser-material interactions and optimizing various laser applications. These experiments involve directing high-intensity laser pulses at different materials to study the resulting craters' size, shape, and morphology. The primary purposes of these experiments include characterizing material properties such as thermal conductivity and resistance to laser-induced damage, developing precise laser-based manufacturing techniques, and enhancing applications in fields like inertial confinement fusion and medical treatments.
Data evaluation is a critical component of crater experiments, involving the collection and analysis of detailed measurements using tools like optical microscopy, scanning electron microscopy (SEM), and profilometry. Quantitative analysis focuses on parameters such as crater dimensions and surface roughness, while qualitative analysis examines morphological features and material responses. Advanced software tools like ImageJ and MATLAB are employed to enhance the accuracy and efficiency of data evaluation.
Challenges in data evaluation include managing data variability, resolution limitations, and interpretation errors. Addressing these challenges involves improving measurement techniques and employing robust analysis methods. The insights gained from these experiments not only advance scientific understanding but also drive innovations in manufacturing, medical treatments, and high-energy physics applications.
Overall, crater experiments and their subsequent data evaluation are integral to leveraging laser technology across multiple domains, offering significant potential for future research and application development.
Recent advances in laser technology and plasmonics, combined with knowledge from heavy-ion collisions, highlight the key role of resonating particles in boosting wave energy absorption, aiding fusion initiation.
In this study, we employ numerical modeling to investigate the interaction between laser radiation pulses and matter doped with gold nanoparticles of various shapes.
We investigate the response of gold-doped materials to short, intense bursts of infrared radiation, with a focus on the ejection dynamics of electrons from nanoantennas of different shapes.
Our analysis involves calculating and examining various properties, such as momentum and energy, of the resulting charges. Specifically, we compare the energies of ionization products under different doping scenarios to identify conditions that produce ions with the highest energy and momentum after a radiation pulse. Virtual experiments are conducted to investigate the effects of nanoantenna dopants with crossed and circular shapes, varying in size.
We track the dynamics of the interaction between the laser radiation and the doped matter, monitoring ionization products and their energies, as well as field intensities around resonating dopants.
These findings are pivotal for future fusion research, especially in the context of high energy short laser ignition pulses within the NAPLIFE project.
We develop a compact experimental setup to accelerate atoms from thin foils and gas targets. The energy and flux of plasma ions are measured with a Thomson parabola spectrometer and nuclear track detectors. We focus on the aneutronic p11B reaction which generates three energetic alpha particles. The yield of fusion products is measured with time-of-flight spectroscopy. We investigate the effect of metal nanoparticles to the yield and energy of the ions and fusion products, too. The plasmonic near field enhancement can locally increase the efficiency of accelerating processes. We test more target geometries with a 30 mJ/40 fs Ti:Sa laser system.
This study explores how gold nanoparticle doping enhances medium absorption under laser infrared pulses of intensities ~10^15 - 10^18 W/cm2. Traditionally, not the particle-in-cell method comes first in mind, however, we can also investigate effects which cannot be considered with common methods. Using numerical modeling and the EPOCH software, we investigate how nanoparticles of various shapes act as resonant nanoantennas. We analyze the absorption characteristics of the medium and calculate ionization product energies for protons, electrons, and ions. Comparative analysis identifies optimal conditions for energy absorption and ion enhancement with nanoparticles of different shapes and sizes, including quadrupole, dipole, and spherical forms.
Additionally, we examine ionization dynamics with quadrupole nanoantennas and address energy absorption saturation.
The standard model of modern cosmology, which is based on the Friedmann–Lemaître–Robertson–Walker metric, allows the definition of an absolute time. However, there exist (cosmological) models consistent with the theory of general relativity for which such a definition cannot be given since they offer the possibility for time travel. The simplest of these models is the cosmological solution discovered by Kurt Gödel, which describes a homogeneous, rotating universe. Disregarding the paradoxes that come along with the abolishment of causality in such space–times, we are interested in the purely academic question of how an observer would visually perceive the time travel of an object in Gödel's universe. For this purpose, we employ the technique of ray tracing, a standard tool in computer graphics, and visualize various scenarios to bring out the optical effects experienced by an observer located in this universe. In this way, we provide a new perspective on the space–time structure of Gödel's model.
Jupiter's magnetosphere is one of the largest natural particle accelerators in our Solar System. Its dynamic processes are governed by the fast rotation of the planet, creating complex current systems and particle transport mechanisms. The Galilean satellites play important roles as plasma sources, influencing the dynamics and distribution of charged particles in the Jovian magnetosphere. Building on the knowledge gained from previous flybys and the Galileo orbiter, the recently launched Jupiter Icy Moons Explorer (JUICE) spacecraft will study the interaction between the Galilean satellites and the rapidly rotating inner magnetospheric plasma environment of Jupiter. The mission will conduct several close flybys with Europa and Callisto to further investigate the possibility of the existence of their subsurface oceanic layers. Additionally, JUICE aims to study in unprecedented detail the unique interaction between Ganymede (the only satellite in our Solar System with an intrinsic magnetic field of its own) and the Jovian magnetosphere. Researchers and engineers from the HUN-REN Wigner Research Centre for Physics, the HUN-REN Centre for Energy Research, and SGF Ltd. have participated in the development of the Particle Environment Package (PEP) instrument onboard JUICE.