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2. What could happen beyond the use of radiation on cultural heritage

Author

Corregidor, Victoria, Cortella, Laurent, Ferreira, Luis M., Alves, Luís C., Bertrand, Loïc, Stols- Witlox, Maartje, Casimiro, M. Helena, Mihaljevic, Branka, Calligaro, Thomas, Thoury, Mathieu, Joosten, Ineke, Marusic, Katarina, Chiari, M., Webb, Sam, Vasquez S., Pablo A., Simon, Aliz, Han, Bumsoo, and Horak, Celina I.

Subjects
radiation technology, cultural heritage preservation
Abstract

The use of gamma-rays, ions, X-rays, electrons, or neutrons is very common for imaging, characterization, and the preservation of cultural heritage materials. Their use provides, for example, knowledge about their composition, they are used as a biocide of organic materials, or for the consolidation of materials. Concerns about the eventual side-effects (immediate and future) induced by radiation in some of these materials are growing among the different communities involved. It is very important to join the expertise, knowledge, and concerns of each radiation group together with conservators to clearly study the eventual cause (mainly due to physico-chemical mechanisms) of these side effects, which can provoke the loss of critical analytical information. Quite often objects are made of heterogeneous or composite materials, so consequences of radiation on a very well-known material can change when other materials are involved. Also important is the documentation of the radiation procedures performed on the objects, including any potential visual side-effect. Such information can be crucial for future radiation experiments or to monitor changes along time. The known side-effects observed in a wide range of materials shows the importance of investing in more research and interdisciplinary work. Some examples are: - Colour changes in transparent materials due to trapping of electrons in the vicinity of impurities ; - Overdoses of radiation can break bonds, induce cross-linking or temperature effects which can modify important properties of materials and in extreme cases affect their mechanical integrity ; - Formation of radicals, which can trigger undesirable chemical changes, such as oxidation, leading to colour changes or surface erosion. - Radiation dosages for fungicidal treatments (typically 5 to 10 kGy) can generate side-effects in sensitive materials like paper. To avoid over-exposure, the main parameters (the radiation dose and the dose rate) must be carefully controlled during radiation and optimized following the ALARA approach. Also important is to control and register the environmental parameters and experimental conditions (inert gas, vacuum, low temperature, low moisture, etc.) that can effectively mitigate some adverse effects. For documentation purposes, it will be also important to unify and clarify concepts used within different communities. For example, a dose of 1 kGy could be considered high for the “ion beam community” but not high enough for the “gamma-ray community”, and more importantly, their effects on the materials under study can be totally different. In this work, examples of visible side effects induced by different types of radiation will be shown. Possible responsible mechanisms and ways of mitigation will be discussed, also focusing on non-visible side effects and suitable approaches to detect and record them for future analysis. All researchers involved in cultural heritage materials using radiation techniques should be aware of the possible side effects that such materials may suffer from radiation and the consequences for their (future) behaviour. Only by understanding the origin of such effects, it will be possible to create strategies, protocols, and risk analysis prior to exposure. Research programs involving different communities and training programs are needed to raise our understanding and transmit knowledge.

Published
2022

4. Artificial Intelligence

Author

Börner, Wolfgang, Rohland, Hendrik, Kral-Börner, Christina, Karner, Lina, Liarokapis, Fotis, Kuroczynski, Piotr, Görz, Günther, Schlieder, Christoph, Bartlett, F. Michael, Turkel, William J., Noback, Andreas, Grobe, Lars Oliver, Dorn, Amelie, Rocha Souza, Renato, Koch, Gerda, Methuku, Japesh, Abgaz, Yalemisew, Myridis, Nikolaos, Sarakatsianou, Dimitra, Tintner, Johannes, Spangl, Bernhard, Melcher, Michael, Kazimi, Bashir, Malek, Katharina, Thiemann, Frank, Sester, Monika, Sarris, Apostolos, Küçükdemirci, Melda, Kalayci, Tuna, Verschoof-Van Der Vaart, Wouter, Landauer, Juergen, Wolf, Julien, Pope-Carter, Finnegan, Johnson, Paul S., Yurchak, Igor, Yurchak, Natalie, Sahaydak, Mykhaylo, Rutkovska, Olga, Biletskyy, Vitaliy, Pfaffenbichler, Franz Xaver, Eysn, Lothar, Lehner, Hubert, Kordasch, Sara Lena, Hartmann, Gerhard, Herzog, Irmela, Bibby, David, Block-Berlitz, Marco, Oczipka, Martin, Bommhardt-Richter, Michael, Brüll, Vanessa, Dorninger, Peter, Studnicka, Nikolaus, Enderli, Livia, Villa, Daniele, Cecco, Lorenzo, Lengyel, Dominik, Toulouse, Catherine, Polig, Martina, Schenkel, Arnaud, Zhang, Zheng, Debeir, Olivier, Parsons, Stephen, Gessel, Kristina, Parker, Clifford, Seales, William, Monamy, Elisabeth, Peter, Sigrid, Frampton, Claire, Barandoni, Cristiana, Giulierini, Paolo, Zamparo, Luca, Faresin, Emanuela, Zilio, Daniel, Bauer, Peter, Kaufmann, Viktor, Sulzer, Wolfgang, Lienhart, Werner, Mikl, Thomas, Seier, Gernot, Somigli, Lapo, Palla, Arianna, Toso, Francesca, Emilio, Giulia, Verdiani, Giorgio, Della Monaca, Gualtiero, Smart, Andi, Mosconi, Cristina, Manchanda, Pikakshi, Gonzales, Paloma, Nagakura, Takehiko, Silvestru, Claudiu, Aryankhesal, Fred Farshid, Danthine, Brigit, Hiebel, Gerald, Lehar, Philipp, Stadler, Harald, Pasquali, Andrea, Giraudeau, Stéphane, Capparelli, Francesco, Galatolo, Olimpia, Cecconi, Eleonora, Perera, Walpola Layantha, Messemer, Heike, Heinz, Matthias, Kretzschmar, Michael, Bruderer, Oliver, Toleva-Nowak, Lena, Anafi, Babatunde, Hyvönen, Eero, Koho, Mikko, Cortella, Laurent, Bertrand, Loïc, Stols-Witlox, Maartje, Mihaljevic, Branka, Ferreira, Luis M., Casimiro, M. Helena, Corregidor, Victoria, Joosten, Ineke, Vasquez S., Pablo A., Marusic, Katarina, Alves, Luís C., Simon, Aliz, Han, Bumsoo, Horak, Celina I., and Wimberger, Sindre

Published
2022
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6. Gamma radiation phytosanitary treatment for Hemiberlesia lataniae (Hemiptera: Diaspididae).

Author

Oviedo, Andrea V., Villagran, María F., Gastaminza, Gerardo A., Willink, Eduardo, Van Nieuwenhove, Guido A., Ruiz, María J., Cazado, Lucas E., Perez, Juliana, Dalto, Yesica M., Horak, Celina I., and Hallman, Guy J.

Subjects
*GAMMA rays, *IRRADIATION, *LATANIA scale, *QUARANTINE, *PHYTOSANITATION
Abstract

The latania scale, Hemiberlesia lataniae (Signoret) (Hemiptera: Diaspididae) is a cosmopolitan and highly polyphagous species present on various hosts of economic importance. As with other scales, H. lataniae is quarantined by importing countries and a single viable insect can cause regulatory action. Ionizing irradiation is a promising phytosanitary treatment that is increasingly used worldwide. This study was conducted to determine a dose of radiation that would serve as a phytosanitary treatment for commodities at risk of carrying H. lataniae. Cobalt-60 gamma ray target doses of 50, 100, 150, and 200 Gy were used to irradiate immature and adult stages of H. lataniae infesting fruits of butternut squash, Cucurbita moschata Duschesne ex Lam (Cucurbitales: Curcubitaceae). Tolerance to irradiation in H. lataniae as measured by mortality was found to increase progressively as follows: first instars < second instars < adults. Adult females irradiated with a target dose of 200 Gy failed to produce offspring beyond the egg stage. Large scale tests involving a total of 31,877 female adults showed that a dose of 209 Gy (the highest dose measured when the target dose was 200 Gy) can serve as a phytosanitary treatment against H. lataniae. These results also support a generic dose of 250 Gy for all scale insects. [ABSTRACT FROM AUTHOR]

Published
2016

7. Gamma radiation phytosanitary treatment against Trialeurodes vaporariorum (Hemiptera: Aleyrodidae).

Author

Gastaminza, Gerardo A., Willink, Eduardo, Van Nieuwenhove, Guido A., Oviedo, Andrea V. F., Dalto, Yesica M., Perez, Juliana, Horak, Celina I., and Hallman, Guy J.

Subjects
*GREENHOUSE whitefly, *GAMMA rays, *IRRADIATION, *QUARANTINE, *PHYTOSANITATION
Abstract

In Argentina the greenhouse whitefly, Trialeurodes vaporariorum Westwood (Hemiptera: Aleyrodidae), is one of the 2 main whitefly pest species affecting several fruit and vegetable crops. Both adults and immature stages (nymphs) are presently feeding on many commercial crops, and a single live insect can cause regulatory actions by importing countries. Irradiation is a promising postharvest phytosanitary treatment that is steadily increasing in use worldwide. Cobalt-60 gamma-ray target doses of 30, 60, 90 and 120 Gy were used to determine the effect on irradiated eggs, 2nd instars and late pupae. The late pupa was the stage most tolerant to irradiation. Based on probit and logit analysis of the data obtained using at least 30,000 late pupae, the estimated doses to provide 99.9968% prevention of adult emergence from irradiated pupae were 170 and 222 Gy. Moreover, when late pupae (2 replicates totaling 33,625) were irradiated with a target dose of 100 Gy (maximum absorbed dose of 108 Gy) only 1,146 (3.4%) emerged as normal-looking adults, and they did not lay any eggs. Egg laying and hatch in the non-irradiated controls was normal. Therefore, 108 Gy should guarantee a secure phytosanitary treatment against T. vaporariorum. [ABSTRACT FROM AUTHOR]

Published
2016

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