Recent advances in nanomechanical and in situ testing techniques: Towards extreme conditions

Nanoindentation based techniques were significantly enhanced by continuous stiffness monitoring capabilities. In essence, this allowed to expand from point-wise discrete measurement of hardness and elastic modulus towards advanced plastic characterization routines, spanning the whole rate-dependent spectrum from steady state creep properties via quasi static flow curves to impact or brittle fracture. While representing a significant step forwards already, these techniques can tremendously benefit from additional or complementary input provided by in situ or operando experiments. In fact, by combining and merging these approaches, impressive advances were made towards well controlled nanomechanical investigations at various non-ambient conditions. Here we will discuss some novel experimental avenues facilitated by deliberate extreme environments, and also indicate how future improvements and enhancements will potentially provide previously unseen insights into fundamental material behavior at extreme conditions.

Automated summary

Nanoindentation techniques have been greatly improved by continuous stiffness monitoring capabilities, allowing for comprehensive characterization of hardness, elastic modulus, and plastic properties. By combining different methods and improving experimental conditions, insights into material behavior under extreme conditions can be achieved.