This presentation highlights the use of Integrated Computational Engineering (ICME) technologies to accelerate development of high-performance materials solutions, enabling lightweighting and increased performance of critical components in e.g. the automotive, aerospace, space and energy industries. With ever increasing demands to meet higher performance and sustainability targets, there is a pressing need for new material solutions that enable lightweight component design. However, developing new material solutions or resolving challenges with existing materials is typically a very lengthy and costly process, involving extensive experimentation through trial-and-error. The use of predictive computational tools has the potential to accelerate materials development, enabling rapid identification and prototyping of solutions, cutting down on lead time and development costs. QuesTek utilizes state of-the-art ICME tools, including physics-based, mechanistic or semiempirical models, material property models, CALPHAD databases and computational tools to capture the key process-structure and structure-property relationships in materials. This presentation will showcase the use of QuesTek’s ICME tools, addressing materials challenges related to e.g. metal additive manufacturing, joining technologies, advanced processing or development of high-performance materials, providing solutions to enable concurrent materials and component design for improved performance and weight efficiency in automotive, aerospace, space or energy applications.