At the 2025 GPU Technology Conference (GTC), one of the most anticipated sessions was a quantum computing panel featuring industry leaders and innovators. The panel, moderated by Jensen Huang, the CEO of NVIDIA, was a groundbreaking discussion that shed light on the rapidly advancing field of quantum computing. Huang, known for his visionary approach to technology, kicked off the session by emphasizing the importance of quantum computing in solving some of the world's most complex problems. He highlighted the potential of quantum technologies to revolutionize areas such as drug discovery, financial modeling, and materials science. Among the panelists were Dr. Michelle Simmons, a pioneer in atomic electronics from the University of New South Wales, and John Preskill, a leading theoretical physicist from Caltech. Both experts delved into the fundamental principles of quantum computing, explaining that unlike classical computers which process information using bits (0s and 1s), quantum computers use qubits. Qubits can exist in multiple states simultaneously thanks to a property called superposition, making quantum computing exponentially more powerful for certain tasks. The conversation also touched on the challenges of quantum computing, such as the issue of quantum coherence and the sensitivity of qubits to environmental disturbances. Dr. Simmons discussed her team's work on creating atomic-scale qubits, which could potentially lead to more stable and reliable quantum computers. John Preskill, on the other hand, talked about the theoretical frameworks being developed to mitigate these challenges and ensure the long-term viability of quantum technologies. Another key point raised during the panel was the integration of quantum computing with existing classical systems. This hybrid approach, where quantum computers are used to tackle specific, computationally intensive tasks and classical computers handle the rest, is seen as a practical step towards widespread adoption. Huang emphasized that NVIDIA is actively exploring ways to facilitate this integration, leveraging its expertise in high-performance computing and AI. The panelists also discussed the implications of quantum computing for industries beyond tech. In pharmaceuticals, for example, quantum simulations could greatly accelerate the discovery of new drugs by modeling molecular interactions with unprecedented accuracy. In finance, quantum algorithms could optimize complex portfolios and risk assessments, leading to more efficient market operations. And in materials science, quantum computing could help design new materials with superior properties, such as more efficient semiconductors and stronger alloys. Despite the excitement, the panelists were realistic about the timeline for quantum computing to reach its full potential. They agreed that significant scientific and technological hurdles must be overcome, but they were optimistic that the pace of progress is accelerating. Dr. Simmons pointed to recent breakthroughs in qubit stability, while Preskill noted the growing interest and investment in quantum research from both the public and private sectors. The session concluded with a discussion on the role of collaboration in advancing quantum computing. Huang stressed the importance of interdisciplinary efforts, bringing together experts from physics, computer science, and engineering. The panelists also called for increased funding and support for quantum education, to ensure that the next generation of scientists and engineers is equipped to lead this revolution. Overall, the quantum computing panel at GTC 2025 was not only informative but also inspiring. It showcased the immense potential of quantum technologies and highlighted the challenges and opportunities that lie ahead. The engagement and optimism of the panelists left the audience excited about the future of computing and its transformative impact on various industries.