As interest in energy-related fields increases, this study delves into the pivotal role of Atomic Force Microscopy (AFM) in propelling forward innovations in energy storage technologies. AFM's capability for nanoscale imaging and characterization is harnessed in battery research, unraveling intricate details of electrodes and electrolytes to enhance performance and lifespan. The analysis of material's properties using AFM aids in the meticulous selection and design of materials for energy storage devices. Moreover, AFM's application in studying thin film materials for solar cells contributes to improving efficiency and durability in photovoltaic systems. In fuel cell research, AFM plays a crucial role in optimizing performance and longevity by characterizing membrane structures. The study of nanogenerators and investigation into nanomaterial properties for advanced energy storage systems further underscore AFM's significance in pushing the boundaries of energy storage technologies. In essence, AFM emerges as a powerful and versatile tool, steering progress in the intricate landscape of energy storage technologies.
Dr. Jake Kim
Senior Application Scientist at Park Systems Headquarters
Dr. Jake brings a wealth of expertise and experience in materials science and engineering, culminating in a Ph.D. from Nanyang Technological University, Singapore. Currently serving as the Manager at Parksystems' Application Technology Center since December 2017, Dr. Jake has led initiatives to enhance nano-mechanical measurement performance for Atomic Force Microscopy (AFM) and establish reliable environments for electrochemical measurement using scanning probe microscopy (SPM). Prior to this, Dr. Jake honed his skills at Nanyang Technological University's Division of Materials Technology, focusing on platform and micro-fluidic chamber designs for AFM and investigating bio-recognition processes using force spectroscopy and AFM with molecular-functionalized tips.
