Who is involved
Before the recent developments in quantum computing, expectations were largely rooted in theoretical advancements and limited practical applications. The global landscape was characterized by a fragmented approach to quantum research, with various institutions and countries vying for leadership in a field that promised revolutionary capabilities. However, the anticipated breakthroughs were often overshadowed by the complexities of quantum mechanics and the challenges of translating theory into practice.
The decisive moment came on March 24, 2026, when SRM University-A.P. hosted a three-day Quantum Computing Conclave alongside a 36-hour national hackathon. This event marked a significant shift in the Indian quantum landscape, showcasing the potential of quantum technologies and fostering collaboration among experts. With the Andhra Pradesh government aiming to establish Amaravati Quantum Valley as one of the top five global hubs for quantum research, the conclave served as a catalyst for innovation and investment.
Immediate effects of this conclave were palpable. Experts in quantum technology, including Sridhar C.V., Mission Director of Amaravati Quantum Valley, and Dhinakaran Vinayagamurthy, Manager of IBM Quantum India, led training sessions and workshops. SRM University-A.P. announced plans to develop a mid-sized quantum computer and a diamond-based quantum computer on campus, positioning itself as a leader in quantum research and education. The hackathon attracted numerous participants, with top performers receiving internship and placement opportunities at the Quantum Research and Centre of Excellence (QRACE), further bridging the gap between academia and industry.
Global investment in quantum technology has exceeded tens of billions of dollars annually, reflecting the urgency and importance of this field. The quantum computing market alone is projected to grow from $2.01 billion in 2025 to $40.45 billion by 2035, with a compound annual growth rate (CAGR) of 36% from 2026 to 2035. This rapid growth underscores the increasing recognition of quantum technology’s potential to revolutionize various sectors, including computing, sensing, and networking.
Experts emphasize that quantum computing utilizes qubits that exist in superposition, enabling calculations to be performed exponentially faster than classical computers. This capability is not just theoretical; it is becoming a reality as institutions like SRM University-A.P. take proactive steps to harness these technologies. Ch Satish Kumar, Vice-Chancellor of SRM University-A.P., stated, “Andhra Pradesh made a promise to India and the world on quantum technology and SRM-A.P. is proud to be part of it.”
As the quantum technology landscape evolves, the implications for India and the global community are profound. Sridhar C.V. remarked, “It is important that India achieves tech sovereignty,” highlighting the strategic importance of developing indigenous capabilities in quantum technologies. The transition from research to practical applications is underway, although experts caution that it will not happen overnight. “Quantum technology is transitioning from research to reality – just not all at once,” they noted, indicating that while progress is being made, challenges remain.
In summary, the developments at SRM University-A.P. represent a pivotal moment in the quantum computing arena, with significant investments and collaborative efforts poised to reshape the future of technology. As institutions and governments rally around quantum research, the potential for groundbreaking advancements is more tangible than ever, promising to unlock capabilities that were once thought impossible.
