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Within archaeological and artistic heritage, there are unique pieces of incalculable value. With these artifacts, it is impossible to conduct traditional studies that would involve cutting, scraping, or modifying the object. For this reason, the development of non-destructive techniques—analysis methods that do not alter the piece in any way—is the only path forward to revealing the secrets of the past.
Imagine you have a Roman coin that, when its surface is analyzed, shows 98% pure silver. Does that mean the entire coin is of that high quality? Not necessarily. Ancient silver-copper alloys undergo a very specific chemical phenomenon over the centuries. The copper on the surface reacts with the environment and wears away or dissolves (a process called leaching), while the silver remains intact. This causes an apparent surface enrichment in silver.
Traditional X-ray surface techniques only penetrate a few microns (a micron is one-millionth of a meter) into the surface. Therefore, a surface analysis might indicate a coin is 98% silver when, in reality, the internal alloy barely reaches 80%. The Roman government could have been devaluing its currency (adding more copper to save money), and the chemistry of time ended up "hiding" that trick.
To solve this puzzle without damaging the artifacts, archaeological science utilizes large facilities such as particle accelerators. The key today lies in combining two distinct techniques:
By cross-referencing data from both technologies, scientists can apply a mathematical correction method. Since copper is known to be the element that disappears from the surface due to corrosion, researchers use copper as a baseline to calculate exactly how much real silver is hidden deep inside the core of the coin.
Knowing the true purity of ancient silver-copper coins (minted, for example, during the Roman Republic between 211 BCE and 86 BCE) is more than just a matter of curiosity. The exact ratio of these metals provides crucial data regarding: