002919408 001__ 2919408
002919408 003__ SzGeCERN
002919408 005__ 20241211231315.0
002919408 0247_ $$2DOI$$9IEEE$$a10.1109/TNS.2024.3437753
002919408 0248_ $$aoai:cds.cern.ch:2919408$$pcerncds:CERN
002919408 035__ $$9https://inspirehep.net/api/oai2d$$aoai:inspirehep.net:2852046$$d2024-12-10T15:03:45Z$$h2024-12-11T05:00:02Z$$mmarcxml
002919408 035__ $$9Inspire$$a2852046
002919408 041__ $$aeng
002919408 100__ $$aKerboub, Nourdine$$jORCID:0000-0003-2163-5681$$uCERN$$uCNES, Toulouse$$uLab. Hubert Curien, St. Etienne$$vCNES, Toulouse, France
002919408 245__ $$9IEEE$$aTemperature Effect on the Radioluminescence of Differently Doped Silica-Based Optical Fibers
002919408 260__ $$c2024
002919408 300__ $$a7 p
002919408 520__ $$9IEEE$$aWe evaluate the temperature effect on the X-ray radiation-induced luminescence (RIL) of differently doped silica fibers obtained via the sol-gel route. Previous investigations showed that these optical materials exhibit interesting dosimetry properties, such as very good detection capabilities and linear response over a large range of dose rate. However, several radiation environments, such as space and particle accelerators, also require a careful assessment of the temperature effect on these properties exploited for dosimetry. With this aim, we characterize their RIL efficiency and spectral dependence at several irradiation temperatures. We demonstrate that all the investigated materials present a nonnegligible temperature dependence of the RIL in the range from -120 °C to 80 °C. The temperature effect on the RIL signal is still compensable via calibration and temperature monitoring.
002919408 542__ $$dIEEE$$g2024
002919408 65017 $$2SzGeCERN$$aDetectors and Experimental Techniques
002919408 6531_ $$9author$$aOptical fibers
002919408 6531_ $$9author$$aRadiation effects
002919408 6531_ $$9author$$aTemperature measurement
002919408 6531_ $$9author$$aOcean temperature
002919408 6531_ $$9author$$aTemperature sensors
002919408 6531_ $$9author$$aMonitoring
002919408 6531_ $$9author$$aIons
002919408 6531_ $$9author$$aEffect Of Temperature
002919408 6531_ $$9author$$aOptical Fiber
002919408 6531_ $$9author$$aSilica-based Optical Fibers
002919408 6531_ $$9author$$aTemperature Dependence
002919408 6531_ $$9author$$aLinear Response
002919408 6531_ $$9author$$aDose Rate
002919408 6531_ $$9author$$aTemperature Monitoring
002919408 6531_ $$9author$$aOptical Materials
002919408 6531_ $$9author$$aSilica Fiber
002919408 6531_ $$9author$$aIonizing Radiation
002919408 6531_ $$9author$$aActive Center
002919408 6531_ $$9author$$aDose Levels
002919408 6531_ $$9author$$aTextile Fibers
002919408 6531_ $$9author$$aPhotomultiplier Tube
002919408 6531_ $$9author$$aSensor Response
002919408 6531_ $$9author$$aTetraethyl Orthosilicate
002919408 6531_ $$9author$$aDose Concentration
002919408 6531_ $$9author$$aPoint Defects
002919408 6531_ $$9author$$aPristine Sample
002919408 6531_ $$9author$$aDosimeter
002919408 6531_ $$9author$$aOptically Stimulated Luminescence
002919408 6531_ $$9author$$aX-ray Machine
002919408 6531_ $$9author$$aRod Responses
002919408 6531_ $$9author$$aLow Dose Rate
002919408 6531_ $$9author$$aContribution Of Channels
002919408 6531_ $$9author$$aResponse Of Fibers
002919408 6531_ $$9author$$aAccelerators
002919408 6531_ $$9author$$acerium
002919408 6531_ $$9author$$acopper
002919408 6531_ $$9author$$adosimetry
002919408 6531_ $$9author$$agadolinium
002919408 6531_ $$9author$$agamma
002919408 6531_ $$9author$$anitrogen
002919408 6531_ $$9author$$aoptical fibers (OFs)
002919408 6531_ $$9author$$aradiations
002919408 6531_ $$9author$$asilica glass
002919408 6531_ $$9author$$aspace applications
002919408 6531_ $$9author$$aX-rays
002919408 690C_ $$aARTICLE
002919408 690C_ $$aCERN
002919408 700__ $$aDi Francesca, Diego$$jORCID:0000-0001-8504-0922$$uCERN
002919408 700__ $$aMorana, Adriana$$jORCID:0000-0002-2842-6324$$uLab. Hubert Curien, St. Etienne
002919408 700__ $$aHamzaoui, Hicham El$$jORCID:0000-0003-2468-3072$$uPhLAM, Villeneuve d'Ascq
002919408 700__ $$aOuerdane, Youcef$$jORCID:0000-0002-7210-0014$$uLab. Hubert Curien, St. Etienne
002919408 700__ $$aBouwmans, Géraud$$jORCID:0000-0001-9107-7115$$uPhLAM, Villeneuve d'Ascq
002919408 700__ $$aHabert, Rémi$$uPhLAM, Villeneuve d'Ascq
002919408 700__ $$aCassez, Andy$$uPhLAM, Villeneuve d'Ascq
002919408 700__ $$aBoukenter, Aziz$$jORCID:0000-0001-9850-5389$$uLab. Hubert Curien, St. Etienne
002919408 700__ $$aCapoen, Bruno$$jORCID:0000-0001-8664-9684$$uPhLAM, Villeneuve d'Ascq
002919408 700__ $$aMarin, Emmanuel$$jORCID:0000-0001-5383-9553$$uLab. Hubert Curien, St. Etienne
002919408 700__ $$aBouazaoui, Mohamed$$jORCID:0000-0002-2624-1166$$uPhLAM, Villeneuve d'Ascq
002919408 700__ $$aRicci, Daniel$$jORCID:0000-0001-5422-5553$$uCERN
002919408 700__ $$aGarcia Alia, Ruben$$jORCID:0000-0001-8030-1804$$uCERN
002919408 700__ $$aMekki, Julien$$jORCID:0000-0002-5801-5921$$uCNES, Toulouse
002919408 700__ $$aGilard, Olivier$$jORCID:0000-0001-5709-1220$$uCNES, Toulouse
002919408 700__ $$aBalcon, Nicolas$$uCNES, Toulouse
002919408 700__ $$aGirard, Sylvain$$jORCID:0000-0002-9804-8971$$uLab. Hubert Curien, St. Etienne$$uIUF, Paris$$vMinistère de l’Enseignement Supérieur et de la Recherche, Institut Universitaire de France (IUF), Paris, France
002919408 773__ $$c2280-2286$$n10$$pIEEE Trans. Nucl. Sci.$$v71$$y2024
002919408 960__ $$a13
002919408 980__ $$aARTICLE