Abstract
Nanocellulose-based materials have recently been used to consolidate degraded cotton painting canvases. Canvas-supported paintings consist of materials that are sensitive to moisture and especially susceptible to environmental fluctuations in temperature and relative humidity (RH). These environmental fluctuations occur in uncontrolled environments found in historic houses and palaces and can lead to hydrolytic degradation and mechanical damage to canvases. To simulate this situation in an experimental setting, canvas samples were mounted in a custom-made closed-cell and subjected to programmed cycles of RH at a controlled temperature while exposed to the neutron beam. Results are presented for both untreated samples and those treated with a polar consolidant, cellulose nanofibrils (CNF(aq)) in water, and an apolar consolidant, a composite of persilylated methyl cellulose with surface silylated cellulose nanocrystals (MC+CNC(h)) in heptane. They were then compared with changes in ionic conductivities as measured by dielectric analysis (DEA) with the same cyclic RH program and temperature. Although the samples were exposed to the same experimental conditions, they presented treatment-specific responses. CNF-treated canvas showed higher hygroscopicity than the untreated sample and facilitated moisture diffusion across the sample to areas not exposed to the environment. A sample treated with MC+CNC(h) retarded moisture diffusion during the increase in RH and could, therefore, afford protection to moisture absorption in uncontrolled environments. Thus, the experimental setup and resulting data provide a pilot study demonstrating the potential of neutron radiography in following and comparing real-time moisture diffusion dynamics in untreated and nanocellulose-consolidated cotton canvases and assisting in validating the overall benefit of the treatment.
Highlights
The long-term preservation of paintings relies on controlling their surrounding environmental conditions and on applying a specific conservation treatment tailored to the painting to be preserved
The sample cell specially designed for our application has been successfully used to test the programmed rate of moisture sorption and desorption in small canvas samples by neutron radiography
It demonstrates the potential of neutron radiography to follow real-time moisture diffusion dynamics
Summary
The long-term preservation of paintings relies on controlling their surrounding environmental conditions (on display and in storage) and on applying a specific conservation treatment tailored to the painting to be preserved. When paintings are displayed in uncontrolled environmental conditions, as found in historic houses and palaces, fluctuations in relative humidity (RH) can lead to cracking of the paint layer and enhanced hydrolytic damage to the supporting canvases.[1] In the worst case, the RH fluctuations will result in a loss of paint accompanied by a loss in strength and elasticity of the painting canvases. Upon reaching this stage of damage, the canvas can no longer effectively support the paint structure.[2] Some conservation treatments for damaged paint layers have used a moisture-based approach. The long-term merits of such synthetic consolidants are
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