This is your Quantum Research Now podcast.

Good afternoon, everyone. I'm Leo, and welcome back to Quantum Research Now. Today, December third, 2025, we're witnessing something extraordinary happening across the quantum landscape, and I need to tell you about it immediately.

This morning, the Israeli Quantum Computing Center deployed the world's first Qolab superconducting qubit device. Now, that might sound like technical jargon, but imagine this: you've been trying to build the world's most fragile bridge using materials that keep vibrating unpredictably. Today, someone handed you a blueprint—and the materials—to finally make it stable. That's what John Martinis, the 2025 Nobel Prize winner in Physics and founder of Qolab, just delivered.

What makes this announcement electrifying is timing and scale. Martinis spent decades understanding how to manipulate quantum information using superconducting qubits—the building blocks of quantum computers. His Nobel Prize recognizes that foundational work. But here's where it gets fascinating: Qolab didn't just theorize. They engineered practical qubits designed to reduce noise and decoherence, the quantum gremlins that have sabotaged researchers for years. Think of decoherence like trying to maintain a whisper in a hurricane. These new qubits are engineered to keep that whisper coherent.

The IQCC collaboration means something profound for our field. Qolab's devices in Madison, Wisconsin are now accessible through cloud infrastructure to researchers worldwide. This democratizes access to industrial-grade quantum hardware. Previously, you needed a massive laboratory and PhD-level expertise. Now, scientists globally can run experiments on technology that just won a Nobel Prize.

Meanwhile, on the commercial side, Horizon Quantum completed assembly of its first in-house quantum computer at their Singapore headquarters. They're not just using quantum computers—they're building them. That's a significant shift. It signals that quantum computing infrastructure is transitioning from laboratory curiosity to deployable technology.

What does this mean for computing's future? Consider this parallel: early computers filled entire rooms. Then came personal computers, then cloud computing. We're witnessing quantum's inflection point. When Nobel Prize-winning physics becomes accessible infrastructure, when multiple companies are simultaneously assembling and deploying quantum systems, we're entering the era where quantum computing becomes practical.

The implications ripple outward. Drug discovery, optimization problems, cryptography, artificial intelligence—fields that seemed perpetually out of reach now have viable pathways. Not in decades. Soon.

We're living through the moment when quantum computing stops being "someday" and becomes "right now."

Thanks for joining me on Quantum Research Now. If you have questions or topics you'd like discussed, email leo@inceptionpoint.ai. Subscribe to our show, and remember, this has been a Quiet Please Production. For more information, visit quietplease.ai.

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