Symposium F.MT02—Multimodal, Functional and Smart Scanning Probe Microscopies for Characterization and Fabrication
Research aimed at understanding the spatially distinct chemical and physical makeup and dynamic processes ongoing at solid-solid, solid-liquid, and solid-gas interfaces is central to accelerating major advances in areas including energy, national security and microbiology research. The goal of this symposium is to bring together pioneers of various advanced scanning probe microscopies (SPM) that are pushing the limits of spatial, chemical and temporal resolution, and breadth of what is measurable in material sciences with the aim of building a more coherent picture of material functionality at the defining length- and time- scales. Advances in SPMs as multifunctional tools for nanoscale studies have by their nature lead to multimodal and ultrasensitive characterization measurements that allow to isolate a myriad of functional properties of surfaces simultaneously or in a correlative manner. This has been achieved in two ways: the in-situ combination of SPMs with other analytical measurement techniques and the enhancement of the resolution of spectroscopy measurements, allowing to dissect among the selective contribution of the different physical and chemical interactions ubiquitously present at the nanoscale. This symposia will focus on topics that that highlight combining high resolution SPM measurements with correlative, chemical, electrochemical and photonic measurements of novel materials as advanced characterization techniques, while also considering advances in nanolithographic fabrication techniques using photon, electron or ion beams and/or local scanning probes to transfer energy, material or induce localized chemical reactions. Emphasis will also be placed on advances in scanning probe force measurements and mapping exploiting novel tip-sample interactions, improved detection sensitivity and widening of circumstances under which they are applied continue to push the frontier in the measurement of a broad range of material, chemical and biological systems. Particular attention will be given to advances and applications in novel approaches to force detection and techniques for probing a variety of surfaces and interactions. In addition, a unifying theme will involve data analytics and machine learning to correlate multimodal data channels.