Abstract
Raman spectroscopy is a well-recognised tool for the analysis of materials in canvas paintings. However, it can be difficult to interpret the peaks of the spectra without the additional context of the artwork such as the age, provenance, or colour. Reflectance spectrophotometry can be used to capture the colour of pigments, dyes, and lacquers, but is seldom used to complement Raman data. Additionally, reflectance spectrophotometry results can be influenced by the surface profile of the painting. To overcome these limitations, this work brings together three different analysis modalities to provide a singular, analytical map of the artwork. Raman spectroscopy was used to conduct the chemical identification of pigments, binding media, and varnish present in a synthetic painting sample. Reflectance spectrophotometry was applied to obtain colour information of the surface paint of the sample. Three-dimensional optical profilometry data was used to characterise the micro topology of the paint surface. These three data sets were spatially matched allowing the recorded spectroscopic data to be displayed with the corresponding colour and surface topography across the paint surface.
Highlights
The conservation of artwork has advanced significantly throughout the past century with the development of innovative and revolutionary technologies
In the Raman Analytical Tools section of the Artwork Analysis Tool, Gaussian functions are used to highlight where major peaks exist in the Raman spectra
Spectrophotometry, and optical profilometry are all important techniques for the characterisation of the materials and surface characteristics that make up painted works of art
Summary
The conservation of artwork has advanced significantly throughout the past century with the development of innovative and revolutionary technologies Technologies such as digital spectrometers [1,2], confocal microscopes [3,4], and improved computer software has expanded our knowledge of the chemical makeup of constituents, such as pigments, binding media, and varnishes for paintings. After a collision has occurred between the photon and the molecule, the energy of the emitted photon will either increase or Sensors 2022, 22, 1442 decrease (anti-Stokes and Stokes Raman scatter respectively) depending upon the ambient state of the molecular system This energy differential can be measured with great accuracy to determine the type of chemical probed
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