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Quantum Computing Leaves Lab, Enters Market: D-Wave's CES 2026 Debut Signals New Era
This is your Quantum Research Now podcast.
# Quantum Research Now Podcast Script
Good evening, this is Leo, your Learning Enhanced Operator, and welcome back to Quantum Research Now. Hold onto your seats, because today we're witnessing something remarkable unfold in real-time.
Just this morning, D-Wave Quantum announced they're bringing their commercial quantum computing systems to CES 2026, and I need to explain why this matters beyond the tech headlines. D-Wave isn't just showing up to a trade show—they're declaring that quantum computing has officially left the laboratory and entered the marketplace. Think of it like the moment electric vehicles stopped being a curiosity and became something Tesla could mass-produce. That's where we are right now.
Here's what makes this significant. D-Wave specializes in something called annealing quantum computers, which work fundamentally differently from the gate-model systems you hear about from Google and IBM. Imagine you're trying to find your way out of a massive maze in pitch darkness. A classical computer would methodically try every single path. A quantum annealer, meanwhile, shakes the entire maze at once, allowing solutions to naturally settle into low-energy states. D-Wave's systems can solve optimization problems in manufacturing, supply chain logistics, and materials science—problems that have plagued industries for decades.
The company's vice president of quantum technology evangelism, Murray Thom, will be presenting a masterclass at CES on January seventh, demonstrating how these machines deliver measurable benefits today, not in some distant future. This is crucial. We're not talking about theoretical advantages anymore. D-Wave has over one hundred organizations currently using their systems, with more than two hundred million problems submitted to their quantum computers to date. Real customers. Real problems. Real solutions.
But here's where it gets even more interesting. Simultaneously, we're seeing a wave of breakthroughs that suggest 2026 might be the year quantum computing becomes genuinely industrialized. Silicon Quantum Computing has achieved fidelity rates reaching 99.99 percent—error correction at levels that rival fault-tolerant thresholds. Atom Computing is demonstrating qubit recycling techniques that keep quantum processors running longer without losing quantum information. These aren't incremental improvements; they're architectural revolutions.
What does this mean for computing's future? Imagine a pharmaceutical company discovering new drug compounds in weeks instead of years, or energy companies optimizing power grids in real-time, or financial institutions solving portfolio optimization problems that classical computers can barely touch. That's not hyperbole—that's the practical reality companies are already experiencing.
The quantum age isn't approaching anymore. We're living in it.
Thank you for joining me on Quantum Research Now. If you have questions or topics you'd like us to explore, email me directly at [email protected]. Please subscribe to Quantum Research Now, and remember, this has been a Quiet Please Production. For more information, visit quietplease.ai.
For more http://www.quietplease.ai
Get the best deals https://amzn.to/3ODvOta
This content was created in partnership and with the help of Artificial Intelligence AI
# Quantum Research Now Podcast Script
Good evening, this is Leo, your Learning Enhanced Operator, and welcome back to Quantum Research Now. Hold onto your seats, because today we're witnessing something remarkable unfold in real-time.
Just this morning, D-Wave Quantum announced they're bringing their commercial quantum computing systems to CES 2026, and I need to explain why this matters beyond the tech headlines. D-Wave isn't just showing up to a trade show—they're declaring that quantum computing has officially left the laboratory and entered the marketplace. Think of it like the moment electric vehicles stopped being a curiosity and became something Tesla could mass-produce. That's where we are right now.
Here's what makes this significant. D-Wave specializes in something called annealing quantum computers, which work fundamentally differently from the gate-model systems you hear about from Google and IBM. Imagine you're trying to find your way out of a massive maze in pitch darkness. A classical computer would methodically try every single path. A quantum annealer, meanwhile, shakes the entire maze at once, allowing solutions to naturally settle into low-energy states. D-Wave's systems can solve optimization problems in manufacturing, supply chain logistics, and materials science—problems that have plagued industries for decades.
The company's vice president of quantum technology evangelism, Murray Thom, will be presenting a masterclass at CES on January seventh, demonstrating how these machines deliver measurable benefits today, not in some distant future. This is crucial. We're not talking about theoretical advantages anymore. D-Wave has over one hundred organizations currently using their systems, with more than two hundred million problems submitted to their quantum computers to date. Real customers. Real problems. Real solutions.
But here's where it gets even more interesting. Simultaneously, we're seeing a wave of breakthroughs that suggest 2026 might be the year quantum computing becomes genuinely industrialized. Silicon Quantum Computing has achieved fidelity rates reaching 99.99 percent—error correction at levels that rival fault-tolerant thresholds. Atom Computing is demonstrating qubit recycling techniques that keep quantum processors running longer without losing quantum information. These aren't incremental improvements; they're architectural revolutions.
What does this mean for computing's future? Imagine a pharmaceutical company discovering new drug compounds in weeks instead of years, or energy companies optimizing power grids in real-time, or financial institutions solving portfolio optimization problems that classical computers can barely touch. That's not hyperbole—that's the practical reality companies are already experiencing.
The quantum age isn't approaching anymore. We're living in it.
Thank you for joining me on Quantum Research Now. If you have questions or topics you'd like us to explore, email me directly at [email protected]. Please subscribe to Quantum Research Now, and remember, this has been a Quiet Please Production. For more information, visit quietplease.ai.
For more http://www.quietplease.ai
Get the best deals https://amzn.to/3ODvOta
This content was created in partnership and with the help of Artificial Intelligence AI
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By Inception Point AiThis is your Quantum Research Now podcast.
# Quantum Research Now Podcast Script
Good evening, this is Leo, your Learning Enhanced Operator, and welcome back to Quantum Research Now. Hold onto your seats, because today we're witnessing something remarkable unfold in real-time.
Just this morning, D-Wave Quantum announced they're bringing their commercial quantum computing systems to CES 2026, and I need to explain why this matters beyond the tech headlines. D-Wave isn't just showing up to a trade show—they're declaring that quantum computing has officially left the laboratory and entered the marketplace. Think of it like the moment electric vehicles stopped being a curiosity and became something Tesla could mass-produce. That's where we are right now.
Here's what makes this significant. D-Wave specializes in something called annealing quantum computers, which work fundamentally differently from the gate-model systems you hear about from Google and IBM. Imagine you're trying to find your way out of a massive maze in pitch darkness. A classical computer would methodically try every single path. A quantum annealer, meanwhile, shakes the entire maze at once, allowing solutions to naturally settle into low-energy states. D-Wave's systems can solve optimization problems in manufacturing, supply chain logistics, and materials science—problems that have plagued industries for decades.
The company's vice president of quantum technology evangelism, Murray Thom, will be presenting a masterclass at CES on January seventh, demonstrating how these machines deliver measurable benefits today, not in some distant future. This is crucial. We're not talking about theoretical advantages anymore. D-Wave has over one hundred organizations currently using their systems, with more than two hundred million problems submitted to their quantum computers to date. Real customers. Real problems. Real solutions.
But here's where it gets even more interesting. Simultaneously, we're seeing a wave of breakthroughs that suggest 2026 might be the year quantum computing becomes genuinely industrialized. Silicon Quantum Computing has achieved fidelity rates reaching 99.99 percent—error correction at levels that rival fault-tolerant thresholds. Atom Computing is demonstrating qubit recycling techniques that keep quantum processors running longer without losing quantum information. These aren't incremental improvements; they're architectural revolutions.
What does this mean for computing's future? Imagine a pharmaceutical company discovering new drug compounds in weeks instead of years, or energy companies optimizing power grids in real-time, or financial institutions solving portfolio optimization problems that classical computers can barely touch. That's not hyperbole—that's the practical reality companies are already experiencing.
The quantum age isn't approaching anymore. We're living in it.
Thank you for joining me on Quantum Research Now. If you have questions or topics you'd like us to explore, email me directly at [email protected]. Please subscribe to Quantum Research Now, and remember, this has been a Quiet Please Production. For more information, visit quietplease.ai.
For more http://www.quietplease.ai
Get the best deals https://amzn.to/3ODvOta
This content was created in partnership and with the help of Artificial Intelligence AI
# Quantum Research Now Podcast Script
Good evening, this is Leo, your Learning Enhanced Operator, and welcome back to Quantum Research Now. Hold onto your seats, because today we're witnessing something remarkable unfold in real-time.
Just this morning, D-Wave Quantum announced they're bringing their commercial quantum computing systems to CES 2026, and I need to explain why this matters beyond the tech headlines. D-Wave isn't just showing up to a trade show—they're declaring that quantum computing has officially left the laboratory and entered the marketplace. Think of it like the moment electric vehicles stopped being a curiosity and became something Tesla could mass-produce. That's where we are right now.
Here's what makes this significant. D-Wave specializes in something called annealing quantum computers, which work fundamentally differently from the gate-model systems you hear about from Google and IBM. Imagine you're trying to find your way out of a massive maze in pitch darkness. A classical computer would methodically try every single path. A quantum annealer, meanwhile, shakes the entire maze at once, allowing solutions to naturally settle into low-energy states. D-Wave's systems can solve optimization problems in manufacturing, supply chain logistics, and materials science—problems that have plagued industries for decades.
The company's vice president of quantum technology evangelism, Murray Thom, will be presenting a masterclass at CES on January seventh, demonstrating how these machines deliver measurable benefits today, not in some distant future. This is crucial. We're not talking about theoretical advantages anymore. D-Wave has over one hundred organizations currently using their systems, with more than two hundred million problems submitted to their quantum computers to date. Real customers. Real problems. Real solutions.
But here's where it gets even more interesting. Simultaneously, we're seeing a wave of breakthroughs that suggest 2026 might be the year quantum computing becomes genuinely industrialized. Silicon Quantum Computing has achieved fidelity rates reaching 99.99 percent—error correction at levels that rival fault-tolerant thresholds. Atom Computing is demonstrating qubit recycling techniques that keep quantum processors running longer without losing quantum information. These aren't incremental improvements; they're architectural revolutions.
What does this mean for computing's future? Imagine a pharmaceutical company discovering new drug compounds in weeks instead of years, or energy companies optimizing power grids in real-time, or financial institutions solving portfolio optimization problems that classical computers can barely touch. That's not hyperbole—that's the practical reality companies are already experiencing.
The quantum age isn't approaching anymore. We're living in it.
Thank you for joining me on Quantum Research Now. If you have questions or topics you'd like us to explore, email me directly at [email protected]. Please subscribe to Quantum Research Now, and remember, this has been a Quiet Please Production. For more information, visit quietplease.ai.
For more http://www.quietplease.ai
Get the best deals https://amzn.to/3ODvOta
This content was created in partnership and with the help of Artificial Intelligence AI