The transition from theoretical quantum mechanics to practical quantum computing represents one of the most significant technological developments of the 21st century. This comprehensive survey examines the evolution from foundational quantum mechanical principles to contemporary quantum computing implementations. We analyze how fundamental quantum phenomena—superposition, entanglement, and unitary evolution—are systematically harnessed to achieve computational advantages over classical systems. The paper provides detailed analysis of key quantum algorithms including Deutsch-Jozsa, Grover's search, and Shor's factorization algorithm, emphasizing their theoretical foundations and computational complexity advantages. We present a comparative evaluation of current hardware platforms including superconducting qubits, trapped ions, photonic systems, and semiconductor quantum dots, analyzing their respective merits, limitations, and scalability prospects. The challenges of quantum error correction, decoherence mitigation, and the path toward fault-tolerant quantum computation are critically examined within the context of the current Noisy Intermediate-Scale Quantum (NISQ) era. This interdisciplinary synthesis bridges theoretical quantum mechanics and practical quantum computing, highlighting the remarkable progress achieved and the substantial challenges that remain in realizing the full potential of quantum computation.
Dr Kola Srimannaryana (Wed,) studied this question.