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Controlling the microstructure of components is of interest to achieve optimal final part properties, i.e., materials by design. The manufacturing process itself can affect a material’s characteristics by changing the microstructure. For example, past research has shown that austenite to martensite phase transformation in stainless steel occurs during deformation. Temperature is known to have a significant influence on this phenomenon. In this paper, the effect of temperature on the austenitic to martensite phase transformation in SS 316L under uniaxial tension is investigated. Both a cooling system and a heat exchanger were employed in a uniaxial tension experimental setup to control the temperature. Tensile specimens were strained to fracture at four temperatures of −15, 0, 10, and 20 °C. Digital imaging correlation (DIC) and a thermal imaging camera were used for tests at 0 °C and above to capture strain and temperature data, respectively. Strain and temperature data could not be obtained at −15 °C due to the DIC paint flaking during testing. X-ray diffraction was used to measure the volume fraction of martensite in both the as-received and the tensile-tested materials. 

By following varying deformation paths, e.g., a linear path to equibiaxial loading versus a bilinear path of uniaxial loading followed by biaxial loading, the same final strain state can be achieved. However, the stress state that the material is subjected to is considerably different due to the varying deformation. This is of interest in a growing field of stress superposition to improve formability and manipulate final part properties in metal forming applications. One potential application is forming patient-specific, trauma fixation hardware with differing strength and weight reduction requirements in various regions. In this paper, experiments were performed on a custom fabricated cruciform machine with the goal of subjecting stainless steel 316L to various deformation paths. A novel cruciform specimen geometry was designed in collaboration with the US National Institute of Standards and Technology to achieve large strain values in the gauge region. Digital Image Correlation was utilized to measure surface strain fields in real time. 

The technology of plasticity primarily refers to processing techniques based on forming technology and the forming process of various metals generally. Metal forming is a vital component to the production of goods worldwide, however, the underlying theme of ICTP2021 were sustained manufacturing, as it relates to metal forming, with interests paid to the impact on industrial applications and fundamental science underpinnings of the field. This conference covered a range of topical areas in metal forming research, representing the most critical, rapidly growing, innovative subject areas (including, but not limited to, Big Data in metal forming, agile metal forming, and the value of, and limits to, simulation), and will bring together a wide array of researchers in this arena, including scientists, engineers, managers, government program officers, professors, and students from across industry, academia, and government. Sessions ran in parallel with as many as five sessions running congruently. The program also included multiple plenary talks, invited speakers, and a robust poster session. This variety of programming offerings provided a breadth of information through in-depth discussions and interaction opportunities. This meeting was open to all interested individuals, with a mixture of attendees from academic research, industry and educational professions, representing both senior and junior investigators, postdoctoral trainees and students. The nine overarching topical areas explored during this international conference included Metal Forming Processes & Equipment; Joining by Forming and Deformation; Microstructure and Damage Development & Characterization; Big Data and Metal Forming; High Speed and Impulse Forming; Agile Metal Forming; Microstructure development by Forming; Technologies to Speed Innovation; and Value of, and Limits to, Simulation.