Monumental effort to save the threatened Viking treasures of Oseberg
© Museum of Cultural History, University of Oslo /
Eirik Irgens Johnsen
The wood fibres of the richly decorated ceremonial wagon
are disintegrated because of the preservation method.
© Museum of Cultural History, University of Oslo /
Eirik Irgens Johnsen
The most famous archaeological trove of Oseberg is a well preserved
and richly decorated Viking ship, in which two ladys from high social
rank have been buried. The ship was not treated with alum.
Norwegian conservators are conducting tests at HZB to halt the degradation of one of the most important cultural assets from the Viking Age
Researchers from the Museum of Cultural History in Oslo, working closely with Helmholtz-Zentrum Berlin (HZB), have been studying ancient wooden Viking artefacts at the synchrotron radiation source BESSY II. The conservators expect this non-destructive method will yield crucial insights into the degradation of these unique works of art. The wooden artefacts come from a Viking grave found in 1904 at Oseberg near the Oslo fjords. The Oseberg finding is considered one of the most important testimonies of the Viking Age and is one of the most frequently visited sights in Norway. Yet, they are now in serious danger of collapse because the wood fibres in the artefacts are disintegrating. The reason is the preservation method widely used a hundred years ago in Scandinavia, by which the artefacts were treated. Now, chemists and conservators of the project Saving Oseberg, which is receiving international support, are trying to save these national treasures of Norway.
By performing tests at the synchrotron radiation source BESSY II at HZB, the conservators from Oslo have examined the condition of the wood to figure out what strategies will work to preserve them in future. “In order to halt the degradation process of the cultural treasures, we have to analyze the chemical processes the preservative has caused in the wood very precisely,” says Dr. Hartmut Kutzke who, as chemist at the Museum of Cultural History in Oslo, is leading the conservation project.
The Norwegian scientists used the infrared beamline IRIS for their studies. Employing very high resolution infrared spectroscopy, the researchers have discerned what chemical changes the material has undergone as well as the composition of the overlapping layers of lacquer that have been applied over its hundred-year history of restoration. “The method works completely non-destructively.
The wood fibres of the richly decorated ceremonial wagon are disintegrated because of the preservation method.
© Museum of Cultural History, University of Oslo / Eirik Irgens Johnsen
With the brilliant synchrotron radiation from BESSY II, we can study with pinpoint accuracy the tiniest samples hardly visible to the eye,” Dr. Ulrich Schade of Helmholtz-Zentrum Berlin describes the advantages of the infrared method.
Alongside the near-complete Viking ship, the burial ground discovered at the Oseberg farm on the Oslofjord contained numerous works of art. This finding from the 9th century counts among the most important testimonies of the Viking Age. At the time of their excavation, some of the the objects were heavily fragmented. At the beginning of the 20th century, restorers preserved the individual pieces of wood, including four ceremonial sleds and one wagon, using a solution of alum (potassium aluminium sulfate). The alum crystallized in the wood, thereby stabilizing the wood structure. Following this treatment, the fragments were assembled using metal pins and screws and finally given a coat of lacquer.
Over the last twenty years, the researchers have seen these valuable wooden Viking artefacts become increasingly brittle. Tests have revealed that the treated wood is exhibiting strongly acidic reactions. The alum, originally used to strengthen the wood, has led to the complete destruction of the cellulose fibres – a main structural component of the wood. “Some of the Viking treasures of Oseberg are in very bad condition. Some are only held together by the outermost layers of lacquer,” Hartmut Kutzke explains.
The researchers have now done infrared studies to see whether the alum has also changed the composition of another important component of the wood – its lignin. Even the metal pins and nails used to hold the wooden pieces together may have triggered catalytic processes in the valuable artefacts and caused unknown interactions with the alum and other materials used in their preservation. Initial results confirm so far that there is no cellulose left in the affected Oseberg artefacts and that the lignin has been strongly modified. At the microscale, the researchers have detected significant differences from other archaeological wood not treated with alum.
Working from these results, the conservators intend to develop new preservation materials for archaeological wood so that they can preserve the Oseberg Viking treasures once again – this time for good. “Our aim is to develop an artificial wood. This could be a type of lignin that will form a new wood structure inside,” project leader Kutzke says. These novel materials could then be employed for preserving wooden cultural treasures all around the world.
- The future of corals – what X-rays can tell usThis summer, it was all over the media. Driven by the climate crisis, the oceans have now also passed a critical point, the absorption of CO2 is making the oceans increasingly acidic. The shells of certain sea snails are already showing the first signs of damage. But also the skeleton structures of coral reefs are deteriorating in more acidic conditions. This is especially concerning given that corals are already suffering from marine heatwaves and pollution, which are leading to bleaching and finally to the death of entire reefs worldwide. But how exactly does ocean acidification affect reef structures?
Prof. Dr. Tali Mass, a marine biologist from the University of Haifa, Israel, is an expert on stony corals. Together with Prof. Dr. Paul Zaslansky, X-ray imaging expert from Charité Berlin, she investigated at BESSY II the skeleton formation in baby corals, raised under different pH conditions. Antonia Rötger spoke online with the two experts about the results of their recent study and the future of coral reefs.
- Energy of charge carrier pairs in cuprate compoundsHigh-temperature superconductivity is still not fully understood. Now, an international research team at BESSY II has measured the energy of charge carrier pairs in undoped La₂CuO₄. Their findings revealed that the interaction energies within the potentially superconducting copper oxide layers are significantly lower than those in the insulating lanthanum oxide layers. These results contribute to a better understanding of high-temperature superconductivity and could also be relevant for research into other functional materials.
- Electrocatalysis with dual functionality – an overviewHybrid electrocatalysts can produce green hydrogen, for example, and valuable organic compounds simultaneously. This promises economically viable applications. However, the complex catalytic reactions involved in producing organic compounds are not yet fully understood. Modern X-ray methods at synchrotron sources such as BESSY II, enable catalyst materials and the reactions occurring on their surfaces to be analysed in real time, in situ and under real operating conditions. This provides insights that can be used for targeted optimisation. A team has now published an overview of the current state of knowledge in Nature Reviews Chemistry.