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outlined in ISO 11403‐1, Plastics‐Acquisition and Presentation of Comparable Multi‐Point Data, and include stress–strain curves at different temperatures, isochronous stress–strain curves developed from tensile creep data, and charpy impact at multiple temperatures.

      The illustrations described above are primarily for mechanical properties, but the increase in testing technology has occurred in almost all other aspects of material testing, including thermal and analytical analysis. Examples include the measurement of the coefficient of thermal expansion and Fourier transform IR analysis (FTIR).

      The coefficient of linear thermal expansion (CLTE), which measures the change in length of a specimen with a change in temperature, was previously measured with analog dilatometers and temperature baths that limited the measurement range from –30 °C to 30 °C, according to ASTM D696. With the advent of composites and high‐temperature polymers, the current use temperature can often vary from –40 °C to 250 °C. Today’s technology employs a Thermo Mechanical analyzer (TMA). The TMA is controlled by a computer and the temperature versus expansion is precisely monitored over a much broader temperature range. ASTM D696 has been revised to reference ASTM E228 for higher temperatures, reflecting the increased temperature control required to measure CLTE at elevated conditions.

      Fourier transform IR analysis, which measures a materials absorption and transmission of infrared light, has been an advancement primarily in the way the spectra, which act as a materials fingerprint, are compared. In the past, the analytical chemist would utilize books of known references and compare scans of the material being analyzed to the references for identifications, often a very time‐consuming task. Today, with computerized data acquisition and libraries consisting of thousands of references, the computer performs the peak matching, which makes identification less time‐consuming, more consistent, and provides complex spectra subtractions for the identification of contaminants.

      In addition to technological advances, the testing industry has witnessed a major increase in the acceptance and use of globally recognized testing standards with a new emphasis on characterizations performed by ISO and IEC (International Electrochemical Committee) test methods. These procedures are truly internationally agreed upon methods adopted under a one nation one vote system and provide the common testing language appropriate to an industry dominated by global markets. CAMPUS (Computer‐Aided Materials Pre‐selection by Uniform Standards), which uses ISO and IEC data, provides material properties in a standardized format so that engineers, designers, and plastics purchasers can now choose materials in an “apples to apples” comparison as never before.

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