The effect of sunlight and UV lamps on EPR signal in nails

Marciniak, Agnieszka; Juniewicz, Małgorzata; Prawdzik-Dampc, Anita; Sawczak, Mirosław

doi:10.1007/s00411-019-00777-2

Cited by 10 publications

(4 citation statements)

References 14 publications

(21 reference statements)

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“…7 b). A lack of any effect of visible light on the EPR signal was also reported by Marciniak et al ( 2019 ) for nails clippings—in their study, the light without any UV component had no effect on the nails’ EPR signal, in contrast to light including a UV component. For the iP1_6S_10Gy sample, the RIS stabilized after the initial light-induced decay and maintained its magnitude about 45 days at about 50% of its value measured shortly after illumination (Fig.…”

Section: Discussionsupporting

confidence: 79%

“…7b). A lack of any effect of visible light on the EPR signal was also reported by Marciniak et al (2019) for nails clippings-in their study, the light without any UV component had no effect on the nails' EPR signal, in contrast Fig. 7 a EPR spectra of the iPhone 6S sample-their background signal (BG), 10 Gy RIS and the spectra after exposure to X-rays to a dose of 10 Gy dose, and after illumination by the CLEO UV lamp (for data point marked in b by the filled diamond).…”

Section: Discussionsupporting

confidence: 62%

“…Sensitivity to light was also proven for other materials used in EPR dosimetry like alanine, where visible light causes fading of radiationinduced radicals, a change in the shape of the spectra, and a decrease in magnitude of the dosimetric signal (Ciesielski et al 2004(Ciesielski et al , 2008. Also in human nails, generation of a strong EPR signal, similar to the radiation-induced signal, by the UV component of light was recently reported by Marciniak et al (2019).…”

Section: Introductionmentioning

confidence: 78%

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The effect of sunlight and UV lamp exposure on EPR signals in X-ray irradiated touch screens of mobile phones

Juniewicz

Marciniak

Ciesielski

et al. 2020

Radiat Environ Biophys

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Electron paramagnetic resonance (EPR) signals generated by ionizing radiation in touch-screen glasses have been reported as useful for personal dosimetry in people accidently exposed to ionizing radiation. This article describes the effect of light exposure on EPR spectra of various glasses obtained from mobile phones. This effect can lead to significant inaccuracy of the radiation doses reconstructed by EPR. The EPR signals from samples unexposed and exposed to X-rays and/or to natural and artificial light were numerically separated into three model spectra: those due to background (BG), radiation-induced signal (RIS), and light-induced signal (LIS). Although prolonged exposures of mobile phones to UV light are rather implausible, the article indicates errors underestimating the actual radiation doses in dose reconstruction in glasses exposed to UV light even for low fluences equivalent to several minutes of sunshine, if one neglects the effects of light in applied dosimetric procedures. About 5 min of exposure to sunlight or to light from common UV lamps reduced the intensity of the dosimetric spectral components by 20-60% as compared to non-illuminated samples. This effect strongly limits the achievable accuracy of retrospective dosimetry using EPR in glasses from mobile phones, unless their exposure to light containing a UV component can be excluded or the light-induced reduction in intensity of the RIS can be quantitatively estimated. A method for determination of a correction factor accounting for the perturbing light effects is proposed on basis of the determined relation between the dosimetric signal and intensity of the light-induced signal.

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Section: Discussionsupporting

confidence: 79%

Section: Discussionsupporting

confidence: 62%

Section: Introductionmentioning

confidence: 78%

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The effect of sunlight and UV lamp exposure on EPR signals in X-ray irradiated touch screens of mobile phones

Juniewicz

Marciniak

Ciesielski

et al. 2020

Radiat Environ Biophys

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“…However, their applicability is limited due to the obvious difficulty in sample acquisition. Initial studies on EPR dosimetry in nail clippings indicated potential large inaccuracies in reconstructed doses, due to the presence of confounding EPR signals generated mechanically in the samples by cutting, and due to the fading of the dosimetric signal caused by exposure of nails to water (Trompier et al 2009a; Marciniak et al 2018) or induction of obscuring EPR signals by light (Sholom et al 2018; Marciniak et al 2019). Therefore, artificial materials in the vicinity of exposed individuals as well as personal belongings could provide better dosimetric materials more convenient in usage, provided that they preserve any radiation-induced EPR signals.…”

Section: Introductionmentioning

confidence: 99%

Time evolution of radiation-induced EPR signals in different types of mobile phone screen glasses

Juniewicz

Ciesielski

Prawdzik-Dampc

2019

Radiat Environ Biophys

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In this study, samples of smart phone touch screen glass sheets and tempered glass screen protectors were examined with respect to their potential application in the dosimetry of ionizing radiation. The glass samples were obtained from various phones with different types of glass. Electron paramagnetic resonance (EPR) spectra of the radiation-induced signals (RIS) are presented and their dose dependence within a dose range of 0–20 Gy. Despite the observed fading with time of the dosimetric components of the signal, the remaining RIS turned out to be strong enough for a reliable dosimetry even 18 month after irradiation. The study also shows that crushing of the glass sheets and water treatment of the samples have no effect on the background and dosimetric EPR signals.

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