The development of quantum computing has undergone significant transformations, from its inception in 20th-century physics theory to the current pursuit of scalable and fault-tolerant systems. Fundamental algorithms and early experimental systems have paved the way for the present era, known as NISQ, which concentrates on enhancing error rates and system reliability. Researchers are now focusing on logical qubits, error correction, and addressing engineering challenges to achieve practical, large-scale quantum computing. This quiet yet profound revolution is redefining the boundaries of computation and cryptography, with far-reaching implications1. As the field continues to advance, it is poised to challenge existing assumptions and create new opportunities. So what matters to practitioners is that quantum computing's progress will inevitably disrupt the status quo, forcing a reevaluation of current cryptographic methods and computational frameworks.