0000000000136807

AUTHOR

Vadim Maratovich Gadelshin

showing 7 related works from this author

Terbium Medical Radioisotope Production: Laser Resonance Ionization Scheme Development

2021

Terbium (Tb) is a promising element for the theranostic approach in nuclear medicine. The new CERN-MEDICIS facility aims for production of its medical radioisotopes to support related R&D projects in biomedicine. The use of laser resonance ionization is essential to provide radioisotopic yields of highest quantity and quality, specifically regarding purity. This paper presents the results of preparation and characterization of a suitable two-step laser resonance ionization process for Tb. By resonance excitation via an auto-ionizing level, the high ionization efficiency of 53% was achieved. To simulate realistic production conditions for Tb radioisotopes, the influence of a surplus of Gd at…

Medicine (General)theranosticsMaterials scienceCERN-MEDICISIon beam530 PhysicsGadolinium610 Medizinchemistry.chemical_elementTerbiumTERBIUMSURFACE PROPERTYIsotope separationlaw.inventionGADOLINIUMR5-920COMPARATIVE STUDYlawIonization610 Medical sciencesLASER RESONANCE IONIZATIONSAPPHIRE LASER [TI]ARTICLERADIOCHEMISTRYisotope separationTANTALUMOriginal ResearchTHERANOSTICSTi:Sapphire laserRISIKO MASS SEPARATORterbiumATOMIC SPECTROMETRYRadiochemistryTi:sapphire laserGeneral Medicine530 PhysikCharacterization (materials science)CONTROLLED STUDYchemistryRISIKO mass separatorION CURRENTMedicineISOTOPE SEPARATIONIONIZATIONAtomic ratiolaser resonance ionizationgadolinium
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Very high specific activity erbium 169Er production for potential receptor-targeted radiotherapy

2019

Erbium 169Er is one of the most interesting radiolanthanides for new potential receptor-targeted β− therapy applications due to its low energy β− emissions, very low intensity ɣ rays and the possibility to use 68Ga or 44Sc as companion for diagnostic in a theranostics approach. Currently it can be produced in reactors through the neutron activation of highly enriched 168Er. The low specific activity of the produced carrier-added 169Er is limiting its use for receptor-targeted therapy. Nonetheless it is used for radiosynoviorthesis of small joints. The aim of this work is to develop a new large-scale production method for the supply of very high specific activity 169Er. Highly enriched 168Er…

Nuclear and High Energy PhysicsHIGH SPECIFIC ACTIVITIESMaterials scienceTargeted Radiotherapychemistry.chemical_elementLASER IONIZATION7. Clean energy030218 nuclear medicine & medical imaginglaw.inventionErbium03 medical and health sciences0302 clinical medicinePRECLINICAL STUDIESlaw[PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex]Production (economics)HIGH SPECIFIC ACTIVITYIrradiationInstrumentationComputingMilieux_MISCELLANEOUSATOM LASERSRadiochemistrySELECTIVE IONIZATIONNuclear reactorERBIUMRESONANT LASER IONIZATIONLARGE SCALE PRODUCTIONSchemistryHigh specific activityER-169030220 oncology & carcinogenesisSEPARATION EFFICIENCYTARGETED RADIOTHERAPYIONIZATIONSpecific activityRECEPTOR-TARGETED THERAPYNeutron activationNUCLEAR REACTORSNuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms
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Detection of the Lowest-Lying Odd-Parity Atomic Levels in Actinium

2020

Two lowest-energy odd-parity atomic levels of actinium, 7s27pP21/2o, 7s27pP23/2o, were observed via two-step resonant laser-ionization spectroscopy and their respective energies were measured to be 7477.36(4) and 12 276.59(2) cm-1. The lifetimes of these states were determined as 668(11) and 255(7) ns, respectively. In addition, we observed the effect of the hyperfine structure on the line for the transition to P23/2o. These properties were calculated using a hybrid approach that combines configuration interaction and coupled-cluster methods, in good agreement with the experiment. The data are of relevance for understanding the complex atomic spectra of actinides and for developing efficien…

FUNDAMENTAL PHYSICSGeneral Physics and Astronomychemistry.chemical_elementHYPERFINE STRUCTURE01 natural sciences7. Clean energyATOMIC SPECTROSCOPYLASER IONIZATION SPECTROSCOPYATOMSCOMPLEX ATOMIC SPECTRALaser coolingIonization0103 physical sciences010306 general physicsSpectroscopyNUMERICAL METHODSHyperfine structurePhysicsHYBRID APPROACHATOM LASERSActinideConfiguration interactionCOUPLED-CLUSTER METHODSACTINIUMMEDICAL ISOTOPE PRODUCTIONActiniumchemistryLASER COOLINGIONIZATIONProduction (computer science)Atomic physicsCONFIGURATION INTERACTIONS
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Laser resonance ionization spectroscopy on lutetium for the MEDICIS project

2017

The MEDICIS-PROMED Innovative Training Network under the Horizon 2020 EU program aims to establish a network of early stage researchers, involving scientific exchange and active cooperation between leading European research institutions, universities, hospitals, and industry. Primary scientific goal is the purpose of providing and testing novel radioisotopes for nuclear medical imaging and radionuclide therapy. Within a closely linked project at CERN, a dedicated electromagnetic mass separator system is presently under installation for production of innovative radiopharmaceutical isotopes at the new CERN-MEDICIS laboratory, directly adjacent to the existing CERN-ISOLDE radioactive ion beam …

Nuclear and High Energy PhysicsCERN-MEDICISIon beamNuclear engineeringchemistry.chemical_element02 engineering and technology01 natural sciencesLASER IONIZATION SPECTROSCOPYIsotope separationlaw.invention010309 opticslawIonizationLUTETIUM0103 physical sciencesDetectors and Experimental TechniquesPhysical and Theoretical ChemistryLarge Hadron ColliderChemistry021001 nanoscience & nanotechnologyCondensed Matter PhysicsLaserAtomic and Molecular Physics and OpticsIon sourceLutetiumRadionuclide therapyISOTOPE SEPARATIONAtomic physics0210 nano-technologyHyperfine Interactions
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MELISSA: Laser ion source setup at CERN-MEDICIS facility. Blueprint

2019

The Resonance Ionization Laser Ion Source (RILIS) has become an essential feature of many radioactive ion beam facilities worldwide since it offers an unmatched combination of efficiency and selectivity in the production of ion beams of many different chemical elements. In 2019, the laser ion source setup MELISSA is going to be established at the CERN-MEDICIS facility, based on the experience of the workgroup LARISSA of the University Mainz and CERN ISOLDE RILIS team. The purpose is to enhance the capability of the radioactive ion beam supply for end users by optimizing the yield and the purity of the final product. In this article, the blueprint of the laser ion source, as well as the key …

Nuclear and High Energy PhysicsEngineeringTechnologyCERN-MEDICISIon beamRESONANCE IONIZATION SPECTROSCOPYNuclear engineeringPhysics Atomic Molecular & ChemicalNUCLEAR MEDICINE01 natural sciencesISOLDElaw.inventionIonRADIOACTIVITYlawION BEAMSLASER RESONANCE IONIZATION0103 physical sciences[PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex]010306 general physicsNuclear Science & TechnologyInstrumentationInstruments & InstrumentationSAPPHIRE [TI]ComputingMilieux_MISCELLANEOUSLarge Hadron ColliderScience & TechnologyMELISSA010308 nuclear & particles physicsbusiness.industryPhysicsION SOURCESLaserLANTHANIDESIon sourcePhysics NuclearResonance ionizationPhysical SciencesISOTOPE SEPARATIONIONIZATIONRADIOACTIVE ELEMENTSbusinessRARE EARTH ELEMENTSSAPPHIRE
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Highly efficient isotope separation and ion implantation of  163Ho for the ECHo project

2019

Abstract The effective electron neutrino mass measurement in the framework of the ECHo experiment requires radiochemically pure 163 Ho, which is ion implanted into detector absorbers. To meet the project specifications in efficiency and purity, the entire process chain of ionization, isotope separation , and implantation of 163Ho was optimized. A new two-step resonant laser ionization scheme was established at the 30 kV magnetic mass separator RISIKO. For ionization and separation, an average efficiency of 69 ( 5 )  stat(4)sys% was achieved using intra-cavity frequency doubled Ti:sapphire lasers. The implantation of undesired 166 m Ho, which is present in trace amounts in the initial  163Ho…

Accelerator Physics (physics.acc-ph)PhysicsNuclear and High Energy PhysicsAtomic Physics (physics.atom-ph)Orders of magnitude (temperature)DetectorAnalytical chemistryFOS: Physical sciencesLaser01 natural sciencesPhysics - Atomic Physics010305 fluids & plasmasIsotope separationlaw.inventionIonIon implantationlawIonization0103 physical sciencesSapphirePhysics - Accelerator Physics010306 general physicsInstrumentationNuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
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Measurement of the laser resonance ionization efficiency for lutetium

2019

Abstract The development of a highly efficient resonance ionization scheme for lutetium is presented. A laser ion source, based on the all-solid-state Titanium:sapphire laser system, was used at the 30 keV RISIKO off-line mass separator to characterize different possible optical excitation schemes in respect to their ionization efficiency. The developed laser resonance ionization scheme can be directly applied to the use at radioactive ion beam facilities, e. g. at the CERN-MEDICIS facility, for large-scale production of medical radioisotopes.

010308 nuclear & particles physicschemistry.chemical_elementMass spectrometry01 natural sciencesLutetiumIsotope separationlaw.inventionchemistrylawIonization0103 physical sciencesSapphireLaser resonancePhysics::Atomic PhysicsPhysical and Theoretical ChemistryAtomic physics010306 general physicsSpectroscopyRadiochimica Acta
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