As is well known, the deterioration of wall paintings due to the capillary rise of water through the walls is a very widespread problem. In this paper, a study of microclimate monitoring, unilateral nuclear magnetic resonance (NMR), and evanescent-field dielectrometry (EFD) was applied to map non-destructively, in situ, and in a quantitative way the distribution of the moisture in an ancient deteriorated wall painting of the eleventh century. Both unilateral NMR and EFD are quite new, fully portable, and non-destructive techniques, and their combination is absolutely new. The approach reported here is proposed as a new analytical protocol to afford the problem of mapping, non-destructively, the moisture in a deteriorated wall painting in a hypogeous building such as that of the second level of St. Clement Basilica, Rome (Italy), where the use of IR thermography is impaired due to the environmental conditions, and the gravimetric tests are forbidden due to the preciousness of the artifact. The moisture distribution was mapped at different depths, from the very first layers of the painted film to a depth of 2 cm. It has also been shown how the map obtained in the first layers of the artwork is affected by the environmental conditions typical of a hypogeous building, whereas the maps obtained at higher depths are representative of the moisture due to the capillary rise of water from the ground. The quantitative analysis of the moisture was performed by calibrating NMR and EFD signals with purposely prepared specimens. This study may be applied before and after performing any intervention aimed at restoring and improving the state of conservation of this type of artwork and reducing the dampness or extracting salts (driven by the variation of moisture content) and monitoring the effectiveness of the performed interventions during the time. This protocol is applicable to any type of porous material.
Moisture and soluble salts are the main causes of degradation of mural paintings, in particular, frescoes. Water is the ‘driving force’ of damage such as the detachment of the painted layer and the whitening of the painting due to the crystallization of salts (efflorescence). Indeed, the appearance of efflorescence itself is related to the alterations caused by moisture in the process of the evaporation of water through the surface of the wall. Early detection of the presence of moisture under the wall surface is therefore essential for avoiding such kind of damage. In this paper a non-invasive microwave system is described which allows the measurement of the moisture content and the detection of salts in frescoes and mural paintings. The system performs a sub-surface measurement with an investigated depth up to about 2 cm. The measurement system consists of an evanescent-field resonant sensor, a network analyser and a numerical code. The method has been validated by measurements performed on some reference materials with known dielectric characteristics. Several tests on moistened plaster samples, some of them containing calcium nitrate at different concentrations, have been performed in order to verify the effectiveness in quantifying the moisture and salt content. In situ investigations have been carried out by measuring both the moisture content and salt content on frescoes in several museums and churches. The preliminary results prove the usefulness of the method as a diagnostic tool for investigating the health status of frescoes.
An open-coaxial probe suitable for measuring the permittivity of
solid materials has been designed and tested. The peculiar
structure of the probe allows an easy and firm contact with the
surface of the material under measurement, resulting in highly
reliable and reproducible dielectric measurements. The
permittivity measurement is absolute, as the calibration procedure
- based on a genetic algorithm - does not require the use of
dielectric standards. The measurement system - including the
probe, a network analyser, and the numerical code to determine the
permittivity from reflection measurements - have been tested on
solid materials of known properties, and used for determining the
dielectric characteristics of several types of wood.
Many applications of microwave energy to wooden materials have been developed in the last few decades, both for treatment and for diagnostic purposes. All these applications require a reliable estimation of the permittivity of the wood species of interest, which is the physical parameter of crucial importance in the absorption of electromagnetic energy. This paper presents results obtained in the dielectric characterization of five wood species in the frequency range from 2 to 3 GHz, including the ISM frequency of 2.45 GHz. Permittivity was measured by an open-ended coaxial-line probe of new design on wood samples conditioned at several moisture levels. The influence of the natural variability of wood characteristics on the measured permittivity was also investigated by a suitable experimental setup consisting of a poplar table including both sapwood and heartwood regions. Finally, a theoretical discussion on the meaning of a scalar measurement on anisotropic dielectrics is conducted in terms of an isotropic-equivalent permittivity, which is related to the permittivity tensor of the dielectric material.
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