How to Preserve Photographic Artworks for the Future Chemical and Physical Interactions and Implications for Conservation Strategies Reijers, Evert Bastiaan Title: How to Preserve Photographic Artworks for the Future: Chemical and Physical Interactions and Implications for Conservation Strategies Utrecht, Utrecht University, Faculty of Science Ph.D. thesis Utrecht University -with ref.- with summary in Dutch ISBN 978-90-393-6657-8 The work described in this thesis was carried out in the Organic Chemistry & Catalysis group, Debye Institute for Nanomaterials Science, Faculty of Science, Utrecht University, Utrecht, The Netherlands How to Preserve Photographic Artworks for the Future: Chemical and Physical Interactions and Implications for Conservation Strategies Het Behoud van Fotografische Kunst voor de Toekomst: Chemische en Fysische Interacties met Implicaties voor Conserverings-strategieën (met een samenvatting in het Nederlands) Proefschrift ter verkrijging van de graad van doctor aan de Universiteit Utrecht op gezag van de rector magnificus, prof. dr. G.J. van der Zwaan, ingevolge het besluit van het college voor promoties in het openbaar te verdedigen op woensdag 11 januari 2017 des middags te 2.30 uur door Evert Bastiaan Reijers geboren op 4 januari 1989 te Ede Promotor: Prof. dr. L.W. Jenneskens The work described in this Ph.D. thesis was financially supported by the NWO Science4Arts programme. Alles van waarde is weerloos -De zeer oude zingt Lucebert Contents Preface 9 Chapter 1 Introduction 15 Chapter 2 Materials in Photographic Art 27 Chapter 3 Free Fatty Acid Efflorescence on Contemporary 57 Photoworks and Canvas Paintings Chapter 4 Factors Affecting the Formation and Extent of Free Fatty 79 Acid Efflorescence on Photoworks and Paintings Chapter 5 Acid-Catalysed Degradation of Photodyes in Modern 97 Chromogenic Photographs Chapter 6 Material Degradation during the Artificial Ageing of 123 Photographic Art Concluding Remarks 139 Summary 143 Samenvatting 149 Dankwoord 155 Biography 159 Publications 161 Preface Ever since prehistoric times, mankind has created art. Even our direct ancestor Homo Erectus is believed to have made engravings, such as those recently discovered on a mollusc shell in Java dated ca. 500,000 years ago.1 The oldest objects recognised specifically as works of art are dated to a period around 35,000-15,000 years ago, and include carvings in stone and animal bones2 as well as painted images such as the well-known cave paintings in Lascaux, France.3 Even the earliest man thus placed value on aesthetic ideals beyond a direct and practical purpose, and these ideals have only become more influential over time. As a wider variety of materials and technologies became available, our ancestors had the opportunity to create more elaborate artworks such as stone statues, paintings on walls and later canvas, and objects made from wood, metals, glass, papyrus, parchment, paper, etc. The evolution of art has accompanied that of mankind into modern times, where plastics, polymer-based paints, synthetic dyes and photographs have become indispensable building blocks to many contemporary artworks. Art and artistic expression have the ability to move and inspire us, and can serve as a way to explore both one’s personal imagination and the world around us. Additionally, artworks teach us important lessons about the era and societal circumstances of their creation, and as such they are an essential record of human history and creativity. Because of the unique cultural, historical and financial value of many objects, efforts to preserve them have attracted interest for a long time. For example, the Vatican appointed an official cleaner for the famous frescoes of the Sistine Chapel as early as 1543.4 In this early period, conservation and restoration of artworks was very much left in the hands of artists themselves, and restorations conducted during this time have sometimes resulted in significant deterioration of these artworks. To better understand the degradation of artworks and how to preserve them, chemists and physicists began to study degradation processes from the 19th century onwards. For example, Michael Faraday conducted research into the degradation of paintings at the National Gallery in London. He studied the effect of London’s air, smoke-filled from extensive coal burning, on paintings, demonstrating that deterioration of paintings increased during periods of fog or high humidity.5 However, due to technical limitations, errors were frequently made in this kind of research, and it is partly for this reason that large museums founded research institutes specifically to investigate the intricacies of art 9 Preface degradation and conservation. The Staatliche Museen zu Berlin in Germany was the first to found such an institute in 1888, and many other museums and institutes followed suit. In this way, scientific investigations became the primary basis for conservation science, and more particularly, the conservation and restoration of valuable cultural heritage. During the course of the 20th century, accepted practices in conservation and restoration of museum art frequently changed. For example, in the 1920s it was common to restore or protect ageing oil paintings by applying a layer of varnish. However, this varnish was found to turn yellow and was able to interact with the underlying paint layer as well, therefore constituting an additional problem rather than a solution.6 In light of such unexpected consequences, the trend in the last decades has shifted towards monitoring and prevention of damage rather than active conservation, so as to leave the artworks as authentic as possible. In order to apply effective preservation or conservation treatments, it is imperative to understand degradation processes as they occur in artworks during ageing. This involves the physical and chemical study of various materials within these artworks, as well as their interactions, surfaces and possible degradation products. The study of artworks in this manner is associated with a unique combination of challenges. Because artworks often have great historical, cultural as well as financial value, samples are either very small or cannot be obtained at all. Microsamples require specialised equipment (e.g., µ-FTIR, µ-Raman) for effective analysis, while other techniques may simply not be applicable. Because the number of samples is limited as well, non-destructive techniques (e.g. reflectance IR) are preferred over destructive techniques (e.g. SEM-EDX) which destroy the original microsample and will therefore hamper further analysis. Because of the inherent limitations and ethical considerations surrounding the collection of (micro)samples from valuable artworks, non-invasive analysis is gaining attention.7 Handheld devices are now available for non-invasive analysis techniques such as FTIR,8 Raman9 and XRF,9,10 and dedicated set-ups are used to map entire artworks, identifying pigments, binders and inorganic materials. These methods have the advantage of providing data on the entire measured area (for example the surface of a painting) rather than relying on spot analysis, thereby providing a more complete image of an artwork. Additionally, certain techniques, notably XRF,11 can yield information about underlying layers, thus revealing initial sketches, modifications, previous restoration treatments and even entire hidden artworks. In this way, mapping techniques are of direct art historical interest besides their utility as tools in restoration efforts. However, mapping techniques can be relatively time-consuming and require rudimentary knowledge, at least, of the material under investigation. Mapping 10