 Computers are now everywhere, smaller and more powerful than ever. They prevent car accidents, coordinate the global supply chain, and integrate into nearly every part of our data lives. Back in 1965, an engineer and businessman named Gordon Moore predicted that engineers would be able to double the number of transistors packed into a single chip every two years for the next decade. Moore's prediction came true for much more than a decade. In 2021, IBM created a chip with components just two nanometers wide, each narrower than a strand of human DNA. This explosion in computing power has led in a remarkable trick of chemistry. Over the past year, the semiconductor chip has become more complicated. Furthermore, it has become more complicated due to the potential of the photoregist. Photoresists are photosensitive residents whose main components are polymers, photosensitizers, and solvents. The part exposed to light undergoes a chemical reaction, changing the dissolution performance of the polymer and the developer, making it possible to create patterns as desired. The principle is used to transfer complex circuits onto the surface of silicon wafers. We at J.S.R. are proud to be part of the world-class leading company in the development and manufacturing of photoregists. Now, the cost of the material development process is increasing and the time is running. For this reason, we don't know how the newly designed material is going to look like, and how it's going to work in real-time, and how it's going to work in real-time. The real world runs on quantum mechanics. Together with J.S.R., we're showing the fantastic potential of these machines. Together with IBM, which is a long-term partner, we're working on the simulation of science on a quantum computer. We've already been able to do the simulation of photoregists with the smallest amount of molecules, and the smallest amount of molecules. Our clients are already using Qiskit Runtime, the world's most advanced quantum programming environment, to explore their potential. We're driving toward the goal of a quantum-centric supercomputer, capable of solving all kinds of problems that are impossible today. We hope that quantum-chemistry simulations on quantum computers will help us build better, faster computer chips, and we expect that same superpower from modeling chemical reactions to drive drug discovery, to lead to better materials for aerospace engineering, and possibly even new methods to combat climate change.