New opportunities and challenges in nuclear physics with high power lasers

Jul 1, 2024, 8:30 AM → Jul 5, 2024, 7:00 PM Europe/Rome

Aula Renzo Leonardi (ECT*)

Chieh-Jen Yang (ELI-NP), Domenico Doria (ELI-NP), Klaus Spohr (ELI-NP), Leonida Gizzi (Istituto Nazionale di Ottica (INO)), Paolo Tomassini (ELI-NP), Vojtech Horny (ELI-NP), Yuji Fukuda (Kansai Photon Science institute, QST)

Google doc for questions/discussion

Important: Registration deadline is 6/6/2024. To register, click here.

An online discussion forum via slack is opened now. It will be used for both remote and in person participators to promote the discussion at any time. We'll also gather questions from there for the discussion section each day. Please join via:
https://join.slack.com/t/newworkspace-llc6164/shared_invite/zt-2kp46c2nm-ReKUCRCPpdfShovoQZ7ryQ
 

How to reach ECT* from hotel (full route of bus 6 can be found on https://www.trentinotrasporti.it/linea-urbana?idLineaAndata=541&idLineaRitorno=542&shift=0#andata ):

Walk to bus 6 stop: Gazzoletti Piazza Dante (or Cavalcavia S.Lorenzo), then take bus 6 (toward villazzano-grotta), get off at: Villazzano-vila tambosi.

Walk from Hotel Accademia to stop of bus 6 (name of stop: Cavalcavia S.Lorenzo)

Walk from hotel Buonconsiglio

*For people opt to online participation: Please still register online with the full length intended (July 1-5 or any other interval). Below the arrival and departure date, there's "Preference in accommodation"---> choose "not needed". And in the "Special requests", please enter "participate remotely via zoom".

Information for Local Support : see here.

     

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Info for researchers in Japan:

This workshop is jointly sponsored by Japan Society for the Promotion of Science.

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This workshop is jointly sponsored by: Mr. Tu-Kuei Hung, director of lujiang construction, Taiwan.

 

 

Laser-driven ion and electron accelerations open a unique opportunity to probe/trigger new phenomena in nuclear physics. The intensive beams produced by high power lasers can generate neutrons/gamma rays which can be orders of magnitude denser both in time and space than classical accelerators. Thus, rare physical events—which were far from reach before—can be studied for the first time. This workshop will bring together interdisciplinary researchers, including the broadly defined nuclear and laser-plasma communities, to share existing ideas and discuss key issues. Topics include (but are not limited to): laser-driven particle accelerations, laser-driven neutron/gamma-ray sources, multi-photon pumping of nuclear isomer states, neutron captures related to nucleosynthesis, gamma-ray lasers and strong QED effects. Progress in these topics will broaden our current theoretical understanding of nature and bring tremendous practical applications. We aim to promote free discussions and initiate collaborative groups across disciplines to explore and tackle this new regime.

 

Scope of the workshop 
For a long time, theoretical and experimental studies in nuclear physics have been focused on single-event/process which occurs at traditional accelerators. However, lots of interesting physics are either rare events and/or to be explored under dense probing beams. New facilities with high-power lasers (e.g., the 10 PetaWatts laser in the Extreme Light Infrastructure Nuclear Physics (ELI-NP)---currently the most powerful in the world)- can generate such dense beams, and provide exciting opportunities to probe/trigger new phenomena, ranging from multi-photon absorption, strong QED effects in nuclear processes, neutron capture and more. Studies in these areas could lead to practical applications which revolutionize our utilization of nuclear power. On the theory side, investigating those extraordinary events challenges our deepest understanding of nature.
 

The main scope of this workshop is to join forces inter-discipline researchers to address those new opportunities and challenges.

Focused topics (but not limited to):

How to optimize the laser-driven beam and its conversion into neutron/gamma-ray to explore new challenges in nuclear physics

• Existing and new schemes/ideas against experimental limitations.
• Model-dependence and convergence in the PIC simulations.
• Smart conversions from proton to neutron, electrons to gamma, etc.
• Estimations of the desired beam properties, i.e., the trade-off between energy and intensity for various nuclear studies.

 

Opportunities in nuclear physics under dense sources

• Multi-photon absorption for nuclear isomer pumping/de-excitations.
• Possible new phenomena and strong QED effects.
• Feasibility of nuclear laser and laser-assisted fusion.
• Neutron capture related to nucleosynthesis.

 

Physics of interested (below are just some examples, any new idea is highly welcome):

With the Laser Plasma based beams, many interesting physics could occur. For example, two-photon-absorption---which has been observed at the atomic level---could happen in the nuclear case. Ultimately, bombarding heavy nuclei with intensive proton or neutron beam could trigger genuine events where two nucleons interact with the target nucleus within a time interval which can be considered simultaneously, and therefore create an interesting scenario involving a direct probe of three-body mechanism.

Several experiments with intensive beams will be completed before this workshop, and new phenomena observed will be discussed also.

Talk duration
Each talk will be 30+10 mins. We plan to have 6-7 talks per day from July 1-4, and 2-3 talks on July 5.

(On-site participation is strongly encouraged, though the entire program will be available via zoom, with discussion enable via slack as well.)

Invited Speakers:

• Julien Fuchs (via zoom), Ecole Polytechnique, France
• Ishay Pomerantz, Tel Aviv University, Israel
• Akifumi Yogo, Osaka University, Japan
• Yasuhiro Kuramitsu, Osaka University, Japan
• Ubirajara van Kolck, IJCLab, France, and University of Arizona, USA
• Harald Griesshammer, George Washington University, USA
• Carlos Bertulani, Texas A&M university-Commerce, USA
• Antonino Di Piazza, University of Rochester, USA
• Adriana Pálffy (via zoom), Max-Planck-Institut für Kernphysik, Germany
• Edison Liang, Rice University, USA
• Yuanbin Wu (via zoom), Max-Planck-Institut für Kernphysik, Germany, and Nankai
  University, China
• Bradley S Meyer, Clemson University, USA
• Jorge Vieira, IST, Portugal
• Karoly Osvay, University of Szeged and ELI-ALPS, Hungary
• Takehito Hayakawa, Kansai Photon Science institute, QST, Japan
• Peter Thirolf, Ludwig-Maximilians-University of Munich, Germany
• Philip Walker (via zoom), University of Surrey, UK
• Matej Lipoglavsek, Jožef Stefan Institute, Slovenia
• Paul McKenna (via zoom), University of Strathclyde, UK

ext_post.pdf

IMG_20240704_114003483.jpg

Monday, July 1

Welcome: Registration and reception

Welcoming and reception.

1 Welcome talk from ECT* director: U. van Kolck

Short welcoming talk: Welcoming talk

A short welcoming talk.

10:15 AM coffee break

2 High yield fast neutron generation with 1kHz repetition rate few cycle lasers

Speaker: Prof. Karoly Osvay

Osvay_Neutron_260701_fin.pptx

3 Positron and photo-neutron creation using a petawatt laser to irradiate high-Z solid targets

Over the past decade, using the Texas Petawatt Laser (TPW, 130 J, 130 fs) at Austin, Texas to irradiate high-Z thick targets(Au, Pt, Re...) at intensities up to 5x10^21 W/cm^2, we have created copious amounts of positrons and photo-neutrons, resulting in super-high densities of emergent positrons and neutrons. We are still in the early stages of exploring potential applications of such high-density positrons and neutrons. A unique feature of TPW-irradiated high-Z dense metal targets is the production of excess high-energy gamma-rays > 8 MeV with a yield many times that expected from hot electron bremsstrahlung. These high energy gamma-rays appear to be concentrated near the giant-dipole resonance (GDR) of high-Z elements (8-20 MeV). They are ideal for photo-neutron and photo-fission reactions. This talk will summarize the large volume of data we have obtained and discuss plans for future research.
Work supported by US DOE DE-SC0024874.

Speaker: Prof. Edison Liang

ECTtalk.pdf

12:05 PM lunch

4 Photon-induced interactions in relativistic heavy ion collisions

Heavy ions provide strong electromagnetic fields that can be used to probe properties of interest in nuclear structure, nuclear astrophysics and particle physics. In this talk I will discuss new developments in understanding the role of the symmetry energy in the equation of state of nuclear matter, nuclear collective phenomena, QED and QCD processes, and other physics phenomena induced by photon-photon and photo-nuclear interactions in reactions with heavy ions.

Speaker: Carlos Bertulani (Department of Physics Texas A&M University-Commerce)

Bertulani-ECT2024WS.pdf

5 Nuclear astrophysics with gamma-ray/neutron provided from high peak power laser

High peak power laser has been developed quickly, which leads to generation of radiations such as gamma-rays and neutrons with energies higher than 1 MeV. These laser-driven radiations have unique features of high flux, ultra-short pulse, and continues energy distribution. These features are suitable for study of nuclear reactions in the universe, such as nuclear photoreactions with high energy gamma-rays in supernova explosions (gamma-process) and nuclear reactions with high-energy neutrons generated by spallation reaction with high energy cosmic-rays. In general, the energy spectrum of particles in stars and cosmic-rays have continues energy distribution, which may be similar to that generated by high peak power laser, and its event may occur in short time scale from ms to s. Neutrons have also important roles for stellar nucleosynesis for production of elements heavier iron. Furthermore, gamma-rays and neutrons may contribute to isotopic abundance anomalies observed in some elements in primitive meteorites. They may be caused by irradiations in parent bodies of meteorites in the solar system. T. Hayakawa et al. have theoretically proposed the experiments using laser-driven gamma-rays to study the nuclear photoreactions in supernovae [1]. Recently, high flux neutron pulses have been generated by the secondary reactions with ion pulses from laser-plasma interactions [2]. Such neutrons can also play an important role for the study of decay acceleration of long-lived radioisotopes which may have been considered by cosmic-ray irradiation in the early solar system [3]. Nuclear isomers are one of key for such studies. We discuss the possibility of experiments in nuclear astrophysics using laser-driven gamma-rays and neutrons.
[1] T. Hayakawa, et al. Quantum Beam Science, 1(1), 3 (2017).
[2] T. Mori, et al. Phys. Rev. C 104, 015808 (2021).
[3] T. Hayakawa, et al. Comm. Phys. 6, 299 (2023).

Speaker: Takehito Hayakawa (National Institutes for Quantum Science and Technology)

Takehito_Hayakawa.pdf

3:00 PM coffee break

6 Nuclear Isomers in Nucleosynthesis

Speaker: Prof. Bradley Meyer

Meyer.pdf

7 Discussion (neutron source and astrophysics)

Host: Klaus Spohr & Vojtech Horny

Tuesday, July 2

8 Nuclear excitation by electron capture perspectives for laser-generated plasmas and electronic vortex beams

online

Speaker: Prof. Adriana Palffy

9 Nuclear excitation by electron capture in electron-ion collisions

online

Speaker: Prof. Yuanbin Wu

10:20 AM coffee break

10 New opportunities in nuclear physics with high-power lasers and multi-photon absorption

I will present some new possibilities, which are very unique for high-power laser systems, to advance nuclear photonics. The main focus will be to show that the multi-photon mechanism could pave a way to circumvent the very challenging problem of isomer pumping/depletion and gamma-ray laser, provided that an intense gamma-flash for laser-plasma interaction is available. The same mechanism might be applied to other high-intensity beams (such as neutron/proton) in the future to gain crucial knowledge of the nuclear man-body forces. By all means, a synergy between nuclear and laser-plasma physics is highly demanded.

Speaker: Chieh-Jen Yang (ELI-NP)

trento24.pdf

11:30 AM Lunch

11 What is Modern Nuclear Theory, and What are some of the pressing questions?

Speaker: Prof. Harald Griesshammer

griesshammer.nuclear-theory-overview.pdf

12 Developments in laser-driven ion acceleration relevant to nuclear physics with lasers

Speaker: Prof. Paul McKenna

McKenna_Laser Nuclear Workshop July2024_W (1).pdf

2:50 PM coffee break

13 Nuclear isomers at the interface

online

Speaker: Prof. Philip Walker

14 Discussion (nuclear excitation and isomers) https://docs.google.com/document/d/1FaVb0eo_yilz83qgg87mdqIDvU1EPhBT4g39bD_Ky4Y/edit?usp=sharing

Host by: Jerry & Klaus

Wednesday, July 3

15 Flying focus beams as a tool to investigate strong-field physics

In a flying focus beam (FFB) the velocity of the focus can be "programmed" and it is independent of the group and the phase velocity of the beam itself. Recent experiments have demonstrated a moving focus over centimeter lengths, i.e., much longer than the Rayleigh length [1]. Scaling this technology to higher power laser pulses would allow one to employ FFBs as a tool for fundamental high-field physics, especially to investigate effects that accumulate with the interaction length. Specifically, by considering an ultrarelativistic electron beam counterpropagating with respect to a FFB, whose focus copropagates with the electrons at the speed of light, we show that the effects of the so-called transverse formation length of radiation on the radiation itself can be enhanced as compared to the case of a conventional Gaussian beam [2]. Analogously, radiation-reaction effects can be rendered measurable at much lower intensities than conventionally required in a similar setup [3]. Finally, we show how FF beams with angular momentum can be an efficient tool to transport ultrarelativistic electron beams over macroscopic distances without significantly spreading on the transverse plane [4].

[1] D. H. Froula, D. Turnbull, A. S. Davies, T. J. Kessler, D. Haberberger, J. P. Palastro, S.-W. Bahk, I. A. Begishev, R. Boni, S. Bucht, J. Katz, and J. L. Shaw, Nat. Photonics 12, 262 (2018).
[2] A. Di Piazza, Phys. Rev. A 103, 012215 (2021).
[3] M. Formanek, D. Ramsey, J. P. Palastro, D. Froula, and A. Di Piazza, Phys. Rev. A 105, L020203
(2022).
[4] M. Formanek, J. P. Palastro, M. Vranic, D. Ramsey, and A. Di Piazza, Phys. Rev. E 107, 055213 (2023).

Speaker: Antonino Di Piazza (Department of Physics and Astronomy, University of Rochester and Laboratory for Laser Energetics, University of Rochester)

Di_Piazza_Trento.pdf

9:40 AM coffee break

16 Two Laser-Driven Nuclear Physics (LDNP) flagship experiments have been identified for the NSF OPAL Laser Facility

Laser-ion acceleration mechanisms provide a unique opportunity for generating radioactive tritium beams, which are currently not available at accelerator facilities. Few datasets exist of tritium-induced reactions involving light, neutron rich nuclei like 6He, 8Li and 11Be. However, these nuclei are of high interest for nuclear science because influence the r-process as “seed nuclei” [Ter01] and are also predicted to exhibit exotic structure [Qua18, Coc12, For05]. A new platform at the OMEGA-EP laser system at the University of Rochester (UR) Laboratory for Laser Energetics (LLE) is now in a position to support nuclear science experimentation [Sch22]. In a pilot study, 10x^13 tritons were accelerated to several MeV and directed onto a deuterated target, producing 108 fusion neutrons. Follow-up experiments using lithium and beryllium targets to measure the cross sections of di-neutron transfer reactions on these light nuclei will be discussed. This material is based upon work supported by the Department of Energy [National Nuclear Security Administration] University of Rochester “National Inertial Confinement Fusion Program” under Award Number(s) DE-NA0004144.

[Coc12] Cockrell et al: “Lithium isotopes within the ab-initio no-core full configuration approach” Physical Review C 86 (2012)
[For05] Forssen et al: “Large basis ab initio shell model investigation of 9Be and 11Be”, Physical Review C 71 (2005)
[Qua18] Quaglioni et al: “Three cluster dynamics within the ab initio no-core shell model with continuum: How many-body correlations and a clustering shape 6He”, Physical Review C 97 (2018)
[Sch22] A. Schwemmlein et al: “First Demonstration of a Triton Beam Using Target Normal
Sheath Acceleration”, Nuclear Inst. and Methods in Physics Research B 522 (2022)
[Ter01] M. Terasawa et al: “New nuclear reaction flow during r-process nucleosynthesis in supernovae: Critical role of light, neutron-rich nuclei’, The Astrophysical Journal, 562 (2001)

Speaker: Dr Chad Forrest (University of Rochester)

Forrest_LDNP_ECT_2024_opal.pdf

17 TBA (review of where we're at with Apollon)

Speaker: Prof. Julien Fuchs

11:30 AM lunch

18 Recent Progress on Heavy-Ion Acceleration: Towards the Fission-Fusion Nuclear Reaction Scheme

The generation of heavy elements in the universe via the rapid neutron-capture process (r-process) lacks direct experimental probing, as the relevant nuclides lie far-off the last known isotopes near the ‘Waiting Point’ at N=126. The proposed ‘fission-fusion’ reaction mechanism aims at investigating this region by using laser-accelerated fissile ions in a two-stage (fission, fusion) scenario, exploiting their unprecedented high bunch density [1]. In a first development step, the acceleration of gold ions is investigated, as recently achieved in our measurement at the PHELIX laser with 500 fs long pulses [2]. In this experiment, the laser-based acceleration of Au ions to kinetic energies above 7 MeV/u was demonstrated. Additionally, individual Au charge states were resolved with unprecedent resolution. This allowed to investigate the role of collisional ionization using a developmental branch of the particle-in-cell simulation code EPOCH [3], showing a much better agreement of the simulated charge state distributions with the experimental ones than when only considering field ionization. This work is presently continued at the Centre for Advanced Laser Applications (CALA), using the ATLAS 3000 laser (800 nm central wavelength, 25 fs pulse length). The laser is focused with an f/2 parabola on Au foils with thicknesses from 200 nm to 500 nm. To analyze the accelerated ion bunch, a Thomson-Parabola Spectrometer was designed to resolve heavy ions in high charge states. Spectroscopically controlled radiative target heating is integrated into the setup in order to facilitate the acceleration of gold ions by removing carbo-hydrate surface contaminations. An integrated IR spectrometer allows for in-situ measurements of the heated foil temperature, while allowing for a simultaneous monitoring with a transmission screen camera to detect possible foil damage [4]. Recent results on Au ion acceleration at CALA will be presented together with preparations for the next stage of the fission-fusion process, i.e. laser-driven fission.
Ultimately, these exploratory experimental campaigns aim at preparing for studies at the 10 PW laser facility at ELI-NP with optimum pulse energy and focused intensity.

[1] D. Habs et al., “Introducing the fission–fusion reaction process: using a laser-accelerated Th beam to produce neutron-rich nuclei towards the N=126 waiting point of the r-process”, Appl. Phys. B 103, 471-484 (2011)
[2] F.H. Lindner et al., “Charge-state resolved laser acceleration of gold ions to beyond 7 MeV/u”, Sci. Rep. 12, 4784 (2022)
[3] M. Afshari et al., “The role of collisional ionization in heavy ion acceleration by high intensity laser pulses”, Sci. Rep. 12, 18260 (2022)
[4] M. Weiser, “Development of a Spectroscopic Real Time Temperature Diagnostic for Laser Heated Thin Gold Foils”, Master Thesis, LMU Munich, 2021

Speaker: Peter Thirolf (LMU Munich)

2024-Thirolf-ECT2024-Heavy-Ion-Acceleration-FissFus-b.pdf

19 TBA

Speaker: Prof. Ishay Pomerantz

2:20 PM coffee break

20 On the feasibility of the laboratory r-process studies with a laser-driven neutron source

Speaker: Dr Vojtech Horny

Talk_VH_long.pptx

21 discussion (strong QED, fission-fusion, neutron application)

Host: Leo Gizzi and Yuji Fukuda

5:20 PM Short Excursion (TBA, mountain hike, etc.)

To be arranged

Thursday, July 4

22 Coherent radiation from nonlinear plasma wakefields in the blowout regime

Coherent light sources, such as free electron lasers, provide bright beams for biology, chemistry, physics and advanced technological applications. As their brightness increases, these sources are also becoming progressively larger, with the longest being several km long (e.g. LCLS). Can we miniaturise these sources and bring them into university, hospital, and industrial-scale laboratories? Plasmas accelerator sources are an attractive solution to this question, but only if their brightness increases several orders of magnitude.

Here, we re-examine the fundamentals of superradiance and temporal coherence by exploring the radiation emitted by collective excitations, such as plasma waves. We show that the trajectory of a collective excitation defines the radiation as if it were a single, finite-sized super-charged particle. By applying this principle to nonlinear plasma waves in the nonlinear blowout regime, we identify new conditions leading to superradiance and temporal coherence in plasma-based accelerators [1]. We find that the plasma density can control the radiation frequency over a wide range, from THz to soft x-ray emission, and possibly beyond. We explore these concepts in theory and through particle-in-cell simulations complemented by the Radiation Diagnostic for Osiris (RaDiO) [2,3].

[1] B. Malaca et al, Nature Photonics 18 (1), 39-45 (2024)
[2] R.A. Fonseca et al, Plasma Physics and Controlled Fusion 55 (12), 124011 (2013)
[3] M. Pardal et al., Computer Physics Communications 285, 108634 (2023)

Speaker: Prof. Jorge Vieira

9:40 AM coffee break

23 Path towards a high-flux neutron source at ELI-NP

Speaker: Prof. Siegfried Glenzer

ECT-Glenzer2024-nodataVersion.pdf

24 Realizing isotopic temperature profiling by using laser-driven neutron source

Non-contact thermometry, including phase-contrast imaging thermography, is one of the key technologies for modern science and industry. However, it is challenging to instantaneously measure the temperature of a specific element inside an object. As a possible solution, we propose Neutron Resonance Absorption (NRA) analysis using a Laser-driven Neutron Source (LDNS). Here, fast neutrons generated from the LDNS are decelerated down to a few eV in energy and pass through a sample consisting of tantalum (Ta) and silver (Ag) plates as a simplified model of a composite object. We measured NRA signals distinctive for the Ta and Ag. We demonstrate that the temporal structure of the NRA signal for Ta is broadened by a Doppler effect when the plate of Ta is heated. We measured the NRA signal as a function of the temperature and found that the Doppler width increases according to the free gas model by Bethe. It should be emphasized that the NRA measurement was performed by a single pulse of neutrons, the temporal duration of which is in an order of 100 ns at the sample. In other words, the NRA signal allow us to obtain the temperature during the 100 ns. This fact indicates that our method enables element (isotope)-sensitive and non-destructive thermometry to monitor the instantaneous temperature rise in dynamical processes.

Speaker: Zechen Lan (Institute of laser engineering, Osaka Univ.)

11:30 AM lunch

25 Electron screening in nuclear reactions

Speaker: Prof. Matej Lipoglavsek

26 Nuclear spallation by irradiating an atomic thin graphene target with an intense laser

Speaker: Prof. Yasuhiro Kuramitsu

Yasu_ETC2024.pdf

2:50 PM coffee break

27 Plasma-Induced Modification of Nuclear β-Decays and Application to Nucleosynthesis

The talk will be focused on the theory behind the interaction of a plasma with a nucleus, and the consequent modification of decay rates through leptonic and hadronic channels. The former will involve a description of the electron contribution to the decay rate, while the latter will focus on nuclear excited and isomeric states. The talk will include some slides on experimental measurement of the process in stable magnetoplasma, and as promised, the last slides will be left open to discuss possible extension of these studies to laser generated plasmas. These studies will improve current models used for r- and s-process nucleosynthesis.

Speaker: Bharat Mishra

Presentation_ECTStar.pptm

28 Nuclear physics measurements with a laser-induced plasma: potential experimental issues and open questions

Speaker: Dr Silvia Pisano

pisanos_nuclear_physics_with_lasers_with_EuPRAXIA (1).pdf

29 discussion (laser-driven sources, reaction, etc.)

host: Yuji Fukuda & Klaus Spohr

8:00 PM Workshop dinner: Restaurant Scrigno del Duomo at 20:00

Restaurant Scrigno del Duomo
Piazza Duomo, 29
38122 Trento TN

Friday, July 5

30 On the possibility of a laser assisted nuclear fusion in micron-scale 14N clusters

Speaker: Prof. Yuji Fukuda

9:40 AM coffee

31 BNCT and HPLS related topic

Speaker: Prof. Klaus Spohr (ELI-NP)

ECTStartTalk-2024.pdf

32 NSF OPAL: A design project to explore physics under extreme conditions

Speaker: Prof. A. di Piazza

Di_Piazza_Trento_NSF_OPAL.pdf

33 Summary and remark

Speaker: Prof. Klaus Spohr (ELI-NP)

11:30 AM lunch