Laboratory Astrophysics & Planetology
https://www.laserlab-europe.eu/transnational-access/find-a-facility/laboratory-astrophysics-planetology
Reproducing in the lab thermodynamic conditions relevant to astrophysical objects or planet interiors and studying the dynamics of related phenomena (e.g. radiative shocks).CELIA (Bordeaux, France)
https://www.laserlab-europe.eu/about-us/partners/celia
CELIA is a centre of excellence in lasers and their interaction with matter. Research is performed on laser development, ultra-short intense laser matter interactions and applications, from the physics of hot dense plasmas to laser-molecule or laser-atom interactions. 3 state-of-the art laser drivers based on Ti:sapphire and Yb:fiber feed 9 fully-equipped end-stations including secondary XUV and X-ray sources.No publisherAtomic and Molecular PhysicsAttophysicsCondensed Matter PhysicsSoft Matter PhysicsPhase Transition PhysicsSurface SciencePlasma PhysicsWarm Dense MatterLaboratory Astrophysics & PlanetologyHarmonicsParticlesRadiationEMP TechniquesNonlinear and Quantum OpticsPhysical Chemistry and Chemical PhysicsPlasma OpticsAmplification and Compression TechniquesInnovative LasingNovel MaterialsMaterials Under RadiationImaging for Life SciencesNovel DetectorsPlasma DiagnosticsAdvanced Laser DiagnosticsMedical ImagingLaser Fusion2023-09-29T09:42:55ZDocumentCLF (Oxfordshire, UK)
https://www.laserlab-europe.eu/about-us/partners/clf
The CLF offers access to five unique laser facilities for multi-disciplinary research. VULCAN operates two target areas: a high energy 1 PW capability and a synchronised 100 TW & 2 kJ/ns capability, both with very flexible configurations for research in high energy density science. GEMINI offers a unique synchronised dual beam capability with 0.5 PW beams operating at one shot every 20 seconds, focussing on plasma accelerators and the generation and application of secondary sources. ARTEMIS has three beamlines utilising HHG, at 1 kHz/800 nm/200 eV and 100 kHz/1700 nm/1 keV (due online shortly), with a wide suite of end stations for pump-probe experiments in ultrafast XUV science. ULTRA is an ultrafast pump-probe laser spectroscopy facility, combining laser, detector and sample manipulation technology to probe ultrafast molecular dynamics. OCTOPUS: a suite of imaging and laser trapping capabilities, such as super-resolution (including cryogenic), confocal, and light sheet microscopy, single molecule imaging/tracking, and focused ion beam SEM.No publisherAtomic and Molecular PhysicsNuclear PhysicsCondensed Matter PhysicsPhase Transition PhysicsSurface PhysicsPlasma PhysicsWarm Dense MatterLaboratory Astrophysics & PlanetologyHarmonicsParticlesRadiationEMP TechniquesNonlinear and Quantum OpticsQuantum PhysicsChemical PhysicsPhysical ChemistrySolvation ChemistryOrganic ChemistryFullerene ChemistryStereochemistryCombustion and CatalysisInorganic ChemistryCoordination ChemistryAnalytic ChemistryCellular and Molecular BiologyBiophysicsStructural BiologyMetabolomicsBotanyNatural Light HarvestingFood SciencePlasma OpticsAmplification and Compression TechniquesNovel MaterialsMaterials Under RadiationImaging for Life SciencesOther Imaging and AnalysisNovel DetectorsAdvanced Laser DiagnosticsLaser ManufacturingOptoelectronicsOrganic ElectronicsEUV LithographyCancer ResearchImmunologyLight Therapy and DisinfectionParasitologyMedical ImagingPharmacologyLaser FusionSolar EnergyEcologyCultural Heritage and Historical Preservation2024-08-29T14:47:10ZDocumentCLPU (Salamanca, Spain)
https://www.laserlab-europe.eu/about-us/partners/clpu
CLPU operates VEGA, a multi Terawatt laser system composed by three independent and synchronised 30 fs long Ti:Sa based-laser pulses: VEGA-3 of 1 PW (at 1Hz), VEGA- 2 of 200 TW and VEGA-1 of 20 TW (both up to 10 Hz). Besides its architecture, the uniqueness of VEGA is that it is a petawatt-class laser system of high-repetition rate.No publisherAtomic and Molecular PhysicsAttophysicsNuclear PhysicsPlasma PhysicsWarm Dense MatterLaboratory Astrophysics & PlanetologyHarmonicsParticlesRadiationEMP TechniquesNonlinear and Quantum OpticsQuantum PhysicsPlasma OpticsAmplification and Compression TechniquesInnovative LasingMaterials Under RadiationImaging for Life SciencesOther Imaging and AnalysisNovel DetectorsAdvanced Laser DiagnosticsLaser ManufacturingCancer ResearchMedical ImagingLaser FusionCultural Heritage and Historical Preservation2024-06-13T07:40:36ZDocumentFELIX (Nijmegen, Netherlands)
https://www.laserlab-europe.eu/about-us/partners/felix
Stichting Katholieke Universiteit, Radboud University Nijmegen, NetherlandsNo publisherAtomic and Molecular PhysicsCondensed Matter PhysicsSoft Matter PhysicsPhase Transition PhysicsLaboratory Astrophysics & PlanetologyQuantum PhysicsChemical PhysicsPhysical ChemistryOrganic ChemistryFullerene ChemistryCombustion and CatalysisInorganic ChemistryCoordination ChemistryAnalytic ChemistryAstrochemistryBiophysicsMetabolomicsFood ScienceNovel MaterialsOptoelectronicsSpintronicsSolar Energy2023-09-29T09:48:05ZDocumentGSI (Darmstadt, Germany)
https://www.laserlab-europe.eu/about-us/partners/gsi
GSI Helmholtzzentrum für Schwerionenforschung in Darmstadt, Germany is an accelerator laboratory hosting PHELIX (Petawatt High-Energy Laser for Ion eXperiments), both for combined laser/accelerator and standalone laser experiments. The PHELIX laser at GSI presently permits two types of operation: Pulses of a duration between 0.5 ns and 20 ns with a widely variable pulse shape and energies up to 1 kJ, and 0.5 ps short-pulse petawatt-class operation. One high-energy and one low-energy laser stand-alone target area are available, as well as a target area for combined laser / linear accelerator ion beam experiments with a dedicated 100 TW proton acceleration beamline. A new target area dedicated to combined laser / synchrotron ion beam experiments will be available by 2021.No publisherPlasma PhysicsWarm Dense MatterLaboratory Astrophysics & PlanetologyParticlesRadiationNonlinear and Quantum OpticsPlasma OpticsEMP TechniquesAdvanced Laser DiagnosticsPlasma DiagnosticsImaging for Life SciencesAmplification and Compression Techniques2023-09-29T09:55:17ZDocumentHILASE (Dolni Břežany, Czech Republic)
https://www.laserlab-europe.eu/about-us/partners/hilase
HiLASE operates two diode-pumped Yb:YAG solid state laser facilities: Bivoj, delivering over 1 kW of average power in 105 J, 10 ns pulses at 10 Hz, for laser shock peening and ion generation, and Perla, a high average power laser platform generating < 2 ps pulses in broad spectral region from 206 nm to 3 microns for laser processing.No publisherPlasma PhysicsLaboratory Astrophysics & PlanetologyParticlesNonlinear and Quantum OpticsAmplification and Compression TechniquesInnovative LasingMaterials Under RadiationNovel DetectorsAdvanced Laser DiagnosticsLaser Manufacturing2020-03-06T08:55:00ZDocumentHZDR (Dresden, Germany)
https://www.laserlab-europe.eu/about-us/partners/hzdr
Helmholtz-Zentrum Dresden Rossendorf, GermanyNo publisherPlasma PhysicsWarm Dense MatterLaboratory Astrophysics & PlanetologyParticlesRadiationNovel DetectorsAdvanced Laser DiagnosticsCancer Research2022-03-21T13:45:46ZDocumentLULI (Coordinator, Palaiseau, France)
https://www.laserlab-europe.eu/about-us/partners/luli-coordinator
LULI operates two multi-beam laser facilities: APOLLON, a Ti:Sapphire shot-per-minute facility offering an exceptional multi-PW peak power, and LULI2000, a highly energetic Nd-glass laser. APOLLON allows exploring high-field physics and generating extreme particle and radiation beams for applications. LULI2000 couples high-energy and high-power laser pulses onto a target together with external high-amplitude pulsed magnetic fields for high-energy-density physics investigation.No publisherAtomic and Molecular PhysicsPlasma PhysicsWarm Dense MatterLaboratory Astrophysics & PlanetologyHarmonicsParticlesRadiationEMP TechniquesCellular and Molecular BiologyPlasma OpticsMaterials Under RadiationPlasma DiagnosticsLaser Fusion2023-09-29T09:56:12ZDocumentPALS (Prague, Czech Republic)
https://www.laserlab-europe.eu/about-us/partners/pals
PALS operates a kJ-class photodissociation iodine laser system at a wavelength of 1315 nm and a pulse duration of 350 ps. This main laser beam is precisely synchronized with a femtosecond Ti:sapphire laser system (up to 1 J, 40 fs) used mainly as a probe beam for plasma parameter measurements.No publisherPlasma PhysicsWarm Dense MatterLaboratory Astrophysics & PlanetologyParticlesRadiationEMP TechniquesPhysical Chemistry and Chemical PhysicsAstrochemistryPlasma DiagnosticsLaser Fusion2023-12-12T10:08:40ZDocument