Rusnai Rahayu, Endang Pratiwi, Nur Hajjeni, Adinda Luminto, Muhammad Yusuf

Quantum Leap: When Computers Transcend the Limits of Classical Logic

Introduction

Quantum leap: when computers transcend the limits of classical logic. Explore quantum computing's revolutionary impact on information technology, transcending classical logic. Learn its principles, potential in cybersecurity, AI, big data, and key challenges.

Abstract

The rapid evolution of information technology has entered a new phase that increasingly challenges the limits of classical computational logic. Quantum computing has emerged as a new computational paradigm that exploits the principles of quantum mechanics to address problems that are computationally infeasible for conventional computers. This study aims to analyze the fundamental concepts of quantum computing, recent technological developments, and its potential implications for the field of information technology. A Systematic Literature Review (SLR) method was employed by analyzing peer-reviewed journal articles and research reports published between 2019 and 2025. The results indicate that quantum computing demonstrates significant potential in areas such as cybersecurity, artificial intelligence, and big data analytics. However, critical challenges remain, including qubit instability, decoherence, quantum error correction, and high implementation costs. This study concludes that quantum computing represents a transformative technological leap that is expected to reshape the future trajectory of global information technology, provided that existing technical and infrastructural challenges can be effectively addressed.

Review

The paper "Quantum Leap: When Computers Transcend the Limits of Classical Logic" addresses a critically timely and significant topic in the landscape of modern information technology. By embarking on a systematic literature review, the authors aim to comprehensively analyze the fundamental concepts, recent technological advancements, and the potential implications of quantum computing. The chosen methodology, spanning peer-reviewed articles and reports from 2019 to 2025, positions this study to offer a current and robust synthesis of the field's rapid evolution, providing a valuable resource for researchers and practitioners alike. A key strength of this study lies in its effective identification and mapping of quantum computing's most promising application domains. The abstract highlights significant potential in areas such as cybersecurity, artificial intelligence, and big data analytics, underscoring the technology's capacity to transcend the limitations of classical computational logic. This detailed identification of high-impact areas not only validates the intense interest in quantum computing but also provides a clear roadmap for future research and development, offering insights into where transformative breakthroughs are most likely to occur. Crucially, the review maintains a balanced perspective by candidly addressing the formidable challenges that still impede the widespread adoption and scalability of quantum computing. Issues such as qubit instability, decoherence, the complexities of quantum error correction, and high implementation costs are rightly identified as critical hurdles. The study's conclusion, that quantum computing represents a transformative leap contingent on effectively addressing these existing technical and infrastructural challenges, is a well-reasoned and realistic assessment, enhancing the credibility and practical utility of this systematic literature review.

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