Exploring the possibility of radiography in emission mode at higher energies: Improving the visualization of the internal structure of paintings
Main Article Content
Abstract
We demonstrated in previous investigations that the internal structure of paintings can be visualized with conventional radiography in transmission mode when paintings have the proper stratigraphy. Unfortunately, there are many paintings that do not result in useful images. This problem can be solved by using radiography in emission mode. With this technique, the painting is irradiated with high energetic X-rays originating from an X-ray tube operating at 100 keV - 320 keV while inside the painting low energetic signals such as photoelectrons or characteristic photons are being generated. These signals escape from the top 10 µm of the painting and are able to illuminate the imaging plate. However, this technique has also some disadvantages. One of them is that it is not able to visualize underlying paintings. In this study, we explored the possibility to enhance the information depth by increasing the energy of the photon source from 100 keV up to 1.3325 MeV (i.e., 60Co source). At the same time, we also studied how the contrast between pigments is generated in emission mode. For this, we used mathematical simulation of particle transport in matter to understand the relation between input particle (particle type such as photon, electron or positron and the energy of the particle), the material being irradiated (element from which it is composed, thickness and density) and the output signal (generated particle types and energy). Finally, we will show that it is possible to image paintings using a 192Ir and even a 60Co source.
Article Details
How to Cite
Schalm, O., Leyva Pernia, D., Willems, P., Cabal, A., & Van Espen, P. (2019). Exploring the possibility of radiography in emission mode at higher energies: Improving the visualization of the internal structure of paintings. Nucleus, (64). Retrieved from http://nucleus.cubaenergia.cu/index.php/nucleus/article/view/663
Section
Ciencias Nucleares
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
Aquellos autores/as que tengan publicaciones con esta revista, aceptan los términos siguientes:
- Los autores/as conservarán sus derechos de autor y garantizarán a la revista el derecho de primera publicación de su obra, el cuál estará simultáneamente sujeto a la Licencia Creative Commons Attribution-NonCommercial 4.0 International (CC BY-NC 4.0) que permite a terceros compartir la obra siempre que se indique su autor y su primera publicación esta revista. Bajo esta licencia el autor será libre de:
- Compartir — copiar y redistribuir el material en cualquier medio o formato
- Adaptar — remezclar, transformar y crear a partir del material
- El licenciador no puede revocar estas libertades mientras cumpla con los términos de la licencia
Bajo las siguientes condiciones:
- Reconocimiento — Debe reconocer adecuadamente la autoría, proporcionar un enlace a la licencia e indicar si se han realizado cambios. Puede hacerlo de cualquier manera razonable, pero no de una manera que sugiera que tiene el apoyo del licenciador o lo recibe por el uso que hace.
- NoComercial — No puede utilizar el material para una finalidad comercial.
- No hay restricciones adicionales — No puede aplicar términos legales o medidas tecnológicas que legalmente restrinjan realizar aquello que la licencia permite.
- Los autores/as podrán adoptar otros acuerdos de licencia no exclusiva de distribución de la versión de la obra publicada (p. ej.: depositarla en un archivo telemático institucional o publicarla en un volumen monográfico) siempre que se indique la publicación inicial en esta revista.
- Se permite y recomienda a los autores/as difundir su obra a través de Internet (p. ej.: en archivos telemáticos institucionales o en su página web) antes y durante el proceso de envío, lo cual puede producir intercambios interesantes y aumentar las citas de la obra publicada. (Véase El efecto del acceso abierto).
La Revista Nucleus solo aceptará contribuciones que no hayan sido previamente publicados y/o procesados, por otra publicación. Cualquier violación ese sentido será considerada una falta grave por parte del autor principal lo cual será objeto valoración por parte del Consejo Editorial, el cual dictaminará al respecto.
References
[1] SCHALM O, VANBIERVLIET L, WILLEMS P, DE SCHEPPER P. Radiography of paintings: limitations of transmission radiography and exploration of emission radiography using phosphor imaging plates. Stud. Conserv. 2014; 59(1): 10-23.
[2] BRIDGMAN CF, KECK S, SHERWOOD HF. The radiography of panel paintings by electron emission. Stud. Conserv. 1958; 3(4): 175-82.
[3] DIK J, JANSSENS K, VAN DER SNICKT G, et. al. Visualization of a lost painting by Vincent van Gogh using synchrotron radiation based X-ray fluorescence elemental mapping. Analytical Chemistry. 2008; 80: 6436-42.
[4] CABAL A, SCHALM O, EYSKENS P, et. al. Comparison of X-ray absorption and emission techniques for the investigation of paintings, X-Ray Spectrom. 2015; 44: 141-148.
[5] SCHALM O, CABAL A, VAN ESPEN P, et. al. Improved radiographic methods for the investigation of paintings using laboratory and synchrotron X-ray sources. J. Anal. Atom. Spectrom. 2011; 26: 1068-1077.
[6] CABAL RODRÍGUEZ AE, PERNIÁ DL, SCHALM O, VAN ESPEN PJM. Possibilities of energy-resolved X-ray radiography for the investigation of paintings. Anal. Bioanal. Chem. 2012; 402: 1471-1480.
[7] HENDRICKS J, MCKINNEY G, TRELLUE H, et. al. MCNPXTM version 2.6.B. Los Álamos National Laboratory. Report LA-UR-06-3248. 2006.
[8] LEYVA PERNÍA D, CABAL RODRÍGUEZ A, SCHALM O, et. al. Study of the main physical processes contributing to image formation in emission radiography using mathematical modelling. Proceedings of the XIV Workshop on Nuclear Physics and VIII International Symposium on Nuclear and Related Techniques WONP-NURT'2013. Havana, Cuba, February 5-8, 2013.
[2] BRIDGMAN CF, KECK S, SHERWOOD HF. The radiography of panel paintings by electron emission. Stud. Conserv. 1958; 3(4): 175-82.
[3] DIK J, JANSSENS K, VAN DER SNICKT G, et. al. Visualization of a lost painting by Vincent van Gogh using synchrotron radiation based X-ray fluorescence elemental mapping. Analytical Chemistry. 2008; 80: 6436-42.
[4] CABAL A, SCHALM O, EYSKENS P, et. al. Comparison of X-ray absorption and emission techniques for the investigation of paintings, X-Ray Spectrom. 2015; 44: 141-148.
[5] SCHALM O, CABAL A, VAN ESPEN P, et. al. Improved radiographic methods for the investigation of paintings using laboratory and synchrotron X-ray sources. J. Anal. Atom. Spectrom. 2011; 26: 1068-1077.
[6] CABAL RODRÍGUEZ AE, PERNIÁ DL, SCHALM O, VAN ESPEN PJM. Possibilities of energy-resolved X-ray radiography for the investigation of paintings. Anal. Bioanal. Chem. 2012; 402: 1471-1480.
[7] HENDRICKS J, MCKINNEY G, TRELLUE H, et. al. MCNPXTM version 2.6.B. Los Álamos National Laboratory. Report LA-UR-06-3248. 2006.
[8] LEYVA PERNÍA D, CABAL RODRÍGUEZ A, SCHALM O, et. al. Study of the main physical processes contributing to image formation in emission radiography using mathematical modelling. Proceedings of the XIV Workshop on Nuclear Physics and VIII International Symposium on Nuclear and Related Techniques WONP-NURT'2013. Havana, Cuba, February 5-8, 2013.