1. Sabine Hossenfelder Quantum Computers Are More Than Just Code Breakers

2. Quantum Computers: Beyond Code Breaking and Into the Impossible

3. The Real Potential of Quantum Computing with Sabine Hossenfelder

4. Are Quantum Computers Only Good for Breaking Codes

5. Code Breaking and Beyond The Surprising Uses of Quantum Computers

6. Quantum Computing’s New Revolution Unlocking More Than Encryption

7. Quantum Computers in 2029: Breaking Codes or Changing the World

8. Quantum Leap: Teaching Students Real-World Quantum Computing

9. Sabine Hossenfelder and the Missed Opportunities of Quantum Computing

10. From Encryption to Innovation The Future of Quantum Computers Unveiled

Sabina Hassenfelder, quantum computers, code breaking, quantum supremacy, Q Day, Google, encryption, RSA encryption, Oratomic, neutral atom arrays, superconducting qubits, zero knowledge proof, quantum circuit simulator, Quantum Rings, Quantum 101, qubits, gate operations, Shor's algorithm, quantum chemistry, material science, optimization, drug discovery, quantum physics, AI in space, Artemis, error mitigation, variational algorithms, quantum error correction, UC San Diego, physics undergraduates, internship

Episode Introduction

Welcome to The INTO THE IMPOSSIBLE Podcast. In today’s episode, we dive into the state of quantum computing, sparked by Sabine Hossenfelder’s viral claim that quantum computers are only truly good for breaking codes—a prospect both thrilling and terrifying. With the timeline for quantum supremacy moving closer than ever—some estimate as soon as 2029—we explore rapid advances in algorithms, hardware, and what these machines are actually useful for, beyond headline-grabbing encryption-breaking.

Brian Keating shares insights from the frontlines at UC San Diego, where undergraduates are already building and programming quantum circuits, hinting at a future far bigger than codebreaking: new frontiers in quantum chemistry, drug discovery, and optimization might be just around the corner. We’ll hear from students whose minds have been blown by hands-on access to quantum computing tools, a new wave of accessible education programs, and the urgent need to grow a workforce ready to unlock quantum’s full potential.

Join us as we break down the recent game-changing breakthroughs, debate the true value and risks of quantum computing, and show you how to get started—no PhD or million-dollar lab required.

Sequence of Topics Covered

Introduction to Sabine Hossenfelder's Video and Its Main Claim

• Brian Keating references Sabine Hossenfelder's viral video about quantum computers 00:00:00

• Sabine's conclusion: quantum computers are mainly useful for breaking codes 00:00:06

• Acknowledgement of the dangers of quantum codebreaking, mentioning Google's advancements (Q Day moved up to 2029) 00:00:16

• Suggestion that there's a bigger story beyond codebreaking, with quantum education occurring at UC San Diego 00:00:29

• Introduction to undergraduates building and programming quantum computers for purposes beyond codebreaking 00:00:43

Major Recent Developments in Quantum Computing

• Three groundbreaking papers released in a week 00:00:58

  • Google algorithm breaking encryption 20× faster, requiring far fewer qubits 00:01:06

  • Oratomic startup claims breaking RSA encryption with just 26,000 qubits 00:01:22

  • New work reducing required qubits by a factor of 10 00:01:53

• Ethical debate over publishing potentially dangerous quantum breakthroughs 00:02:03

Historical Context and Current Acceleration

• Comparison to early computing experiences in the 1980s 00:02:16

• Analogy between early computer access and the evolution of quantum computing 00:02:54

• Quantum simulators like Quantum Rings now available for free, enabling broad access 00:03:11

Transformative Potential of Quantum Computing

• Bob Wold on quantum computing's potential societal impact 00:03:27

  • Drug discovery and treatment (e.g., curing cancer)

  • Improved energy storage and battery efficiency for EVs

  • Sustainable material discovery

  • Optimized supply chains, potentially solving world hunger

• The rapid acceleration of quantum progress—Q Day timeline moved up from 2035–2040 to 2029–2030 00:04:21

• Warnings about the dangers of undetected codebreaking ("things happening in the dark") 00:04:42

Practical Utility and Tooling Revolution

• Brian Keating discusses the current real-world utility of quantum computers outside of code-breaking 00:04:50

• Limited progress in material science, chemistry, optimization, and financial tasks 00:04:56

• The real shift isn't in current applications, but in improved tools and accessibility 00:05:10

• Introduction to Quantum 101—a free, accessible quantum computing course 00:05:33

  • Simulator lets users work with hundreds of qubits and millions of gate operations

  • Same underlying technology as Google and IBM

  • Real quantum hardware access via the same code for different providers

Details of the Quantum 101 Course

• Overview of course content and structure 00:06:14

  • Covers single qubit gates, entanglement

  • Grover's search, quantum Fourier transforms, Shor's algorithm

  • Quantum noise, error mitigation, variational algorithms, quantum error correction

Student Experiences and Testimonials

• Undergraduate feedback on learning quantum computing 00:07:37

  • Demystification of quantum physics concepts

  • Surprise at the range of qubit platforms (neutral atoms, superconducting, photons)

  • Quick progress from zero experience to running quantum algorithms

Career and Internship Opportunities

• Internships offered by Quantum Rings for summer 2026 00:08:36

• Details about the company’s global collaborations and technical reach 00:09:10

• Encouragement to students to apply and start learning now

Quantum Rings’ Mission and Offerings

• Bob Wold describes democratizing quantum computing 00:09:38

  • Simulators for developing future quantum applications on classical hardware

  • Free access for students and personal use

  • Open Quantum platform for running experiments on real quantum computers

The Core Bottleneck: Expertise, Not Just Physics

• Brian Keating emphasizes that the main limitation is the number of trained quantum developers 00:10:58

• Call to action for more people to enter the field and for accessible training tools

Reframing the Debate and Conclusion

• Brian Keating argues Sabine missed the revolutionary effect of democratized tools 00:11:26

• Analogy to early days of personal computing and the unknown potential 00:11:42

• Encouragement to watch Sabine's video, try Quantum 101, and engage with the field 00:11:57

Additional Resources and Closing Remarks

• Links to Sabine's and John Preskill's videos for further learning 00:11:59

• Final encouragement for audience interaction and future episodes 00:12:26

🚀 Exciting developments in quantum computing! After watching Sabine Hossenfelder’s viral video on the risks—and opportunities—of quantum computers, here’s what you need to know now:

🔑 3 Key Takeaways:

• Quantum computing breakthroughs are accelerating: Recent papers show major advances in code-breaking algorithms, shrinking the required number of qubits from millions to just hundreds of thousands—and potentially making “Q Day” (when quantum computers can break current encryption) arrive years sooner than expected.

• Opportunities go beyond code breaking: While Brian Keating acknowledges the threat to encryption, the real story is about what comes next. Quantum computers have potential applications in drug discovery, materials science, optimization, and much more—if we have the talent and tools to build the right quantum circuits and algorithms.

• Quantum education is being democratized—right now: You no longer need access to a cutting-edge lab or expensive hardware to learn quantum computing. Platforms like Quantum Rings offer free simulators and courses (Quantum 101), letting anyone run powerful quantum circuit simulations and even access real quantum hardware. The talent pipeline is opening up, and companies are already hiring interns for 2026!

If you’re a student, researcher, or just curious, now’s the perfect time to dive in and start experimenting. Let’s build the future together!

#quantumcomputing #innovation #careerdevelopment #AI #STEM

🚀 Quantum Computing: More Than Just Code Breaking 🧵

1/ Did you know Google just moved up "Q Day"—the day quantum computers break our encryption—to 2029? That's less than 3 years away. Encryption might never be the same. 😱 (Brian Keating at 00:00:16)

2/ My friend Sabina Hassenfelder says quantum computers are only good for code breaking—and yes, recent breakthroughs prove that's terrifyingly close. But that's not the whole story. (Brian Keating at 00:00:06)

3/ THREE groundbreaking papers just dropped:

• Google found an algorithm that breaks encryption 20x faster, slicing the required qubits from 10 million to 500k.

• Another team claims RSA encryption could fall with only 26k qubits—in 10 days.

• One group slashed the qubit estimate by 10x AGAIN.
  (Brian Keating at 00:00:58, 00:01:22, 00:01:59)

4/ Researchers are so spooked they’re debating if these results should even be published. Imagine scientists debating if knowledge is too dangerous! (Brian Keating at 00:02:03)

5/ But the biggest story isn't in these headlines—it's in the hands of students and YOU. Right now, undergrads at UCSD are building, coding, and simulating quantum computers, aiming for the Moon, literally! (Brian Keating at 00:00:29, 00:00:43)

6/ The real revolution? Tooling and ACCESS. Five years ago, quantum computing meant long waits and clunky results. Today, with @QuantumRings, anyone can simulate hundreds of qubits on their own laptop, for free. 📱💻 (Brian Keating at 00:03:11)

7/ There’s a free course—Quantum 101—taught not from textbooks, but from real quantum labs. From zero skills to building quantum algorithms in weeks. No paywall. No catch. (Brian Keating at 00:06:14)

8/ What happens when you put real quantum tools in the hands of curious minds? Students are running Shor’s algorithm on their MacBooks. Freshmen are landing internships at top labs. (Brian Keating at 00:08:19)

9/ The future’s bottleneck isn’t physics—it’s PEOPLE. Right now, only a few thousand can build a quantum circuit. We need MILLIONS. Now, everyone finally has a way in. (Brian Keating at 00:11:03)

10/ So yes: quantum computers could break every digital secret. But that's just the starting gate. The true potential—for curing cancer, fixing supply chains, and optimizing the world—is up to US to discover. (Bob Wold at 00:03:27)

11/ Want to join the revolution or just play Oregon Trail? (Brian Keating at 00:11:46) The tools are free. The impact? Only limited by imagination.

12/ Go learn, build, and show us what YOU invent. The next era of computing is here, and you don’t need a PhD—or a million dollars—to get started.

🔗 [Quantum 101 course info inside the full video!]

#QuantumComputing #FutureTech #QDay #STEM #AI #WomenInSTEM #EdTech

The INTO THE IMPOSSIBLE Podcast Newsletter

Episode Highlight: Sabine Hossenfelder Quantum Computers

Quantum Computing: Breaking Codes—and Beyond

This week on INTO THE IMPOSSIBLE, we take a deep dive into the rapidly evolving world of quantum computing, inspired by Sabine Hossenfelder’s viral video and recent headline-grabbing breakthroughs in the field. Quantum computers are moving from theory to practical impact faster than anyone predicted, and we’re here to help you stay ahead of the curve.

🚨 Quantum Supremacy Moves Closer

• Recent papers show algorithms that can break encryption up to 20 times faster, requiring dramatically fewer qubits—possibly accelerating the infamous Q Day to as soon as 2029!

• Startups and tech giants are racing toward scalable quantum machines, with new architectures promising to break today’s cryptography in days—not years.

• The implications? All our financial data, bitcoin, government secrets, and personal info could be at risk unless we act now (01:00).

🌎 But There’s More Than Code Breaking…

While Brian Keating agrees with Bob Wold and Sabine about the code-breaking prowess of quantum computers, he emphasizes a bigger story: the revolution is not just in theory, but in accessible quantum tooling and education.

• Now, anyone can simulate hundreds of qubits and millions of gate operations right on their own laptop—for free!

• The free Quantum 101 course by Quantum Rings gives you hands-on, practical training to build and experiment with quantum circuits (05:33).

• Real-world applications in drug discovery, materials science, optimization, and artificial intelligence are just waiting for the next generation of creative minds.

👩‍🚀 Why This Matters NOW

“The bottleneck isn’t physics. The bottleneck is people.”
— Brian Keating (10:58)

• There are only a few thousand quantum developers worldwide. We need hundreds of thousands.

• Quantum Rings is partnering with over 250 universities, bringing free, high-fidelity simulation and real quantum hardware access to students and enthusiasts.

• Internship alert: Quantum Rings is taking applications for their 2026 summer program—get hands-on experience at the cutting edge!

✅ Get Involved

• Try the Quantum 101 course for free—no credit card required, and no quantum background needed.

• Share what you build! Brian Keating wants to hear from you.

• Watch Sabine Hossenfelder’s original video and our full episode for a rounded perspective on promise and peril.

Stay curious. Stay bold. The future is not just approaching—it’s here and it’s up for grabs.

👉 If you want to go deeper, check out our long-format interview with quantum computing pioneer John Preskill.
Subscribe, comment, and let us know what impossible questions YOU want answered!

— Your INTO THE IMPOSSIBLE Team

You’re receiving this email because you subscribed to the INTO THE IMPOSSIBLE Podcast newsletter. To unsubscribe, click here.

Discussion Questions

1. What are the main concerns raised by Brian Keating and Sabine Hossenfelder regarding the implications of quantum computers breaking encryption, and how soon might this become a real threat according to recent research?

2. How does Brian Keating argue that the focus on code breaking misses the broader potential of quantum computing, and what examples do they provide to illustrate this point?

3. In what ways has access to quantum computing evolved over the past five years, and what tools or educational resources are now available to students and the public?

4. Bob Wold discusses the transformative potential of quantum computers in fields like medicine, energy, and supply chains. Which potential application do you find most compelling or urgent, and why?

5. According to Brian Keating, what is currently the biggest bottleneck to broader progress in quantum computing applications beyond code breaking?

6. How might mass education and programs like Quantum 101 impact the pace and direction of quantum technology development?

7. Brian Keating mentions the ethical debate among researchers regarding the publication of sensitive quantum algorithms. What are the arguments for and against sharing these breakthroughs openly?

8. How does Brian Keating compare the current state of quantum computing to the early era of personal computers, and what lessons can be drawn from that analogy?

9. What role do startups and collaborations with universities, such as Quantum Rings, play in democratizing and advancing quantum computing research?

10. After listening to the discussion about quantum computing’s future, how do you personally feel about the balance between its potential opportunities and risks?

✅ Quantum computers: breakthrough tool or just code-breaking machines?
✅ Brian Keating tackles Bob Wold's bold claims about quantum computing's real-world impact.
✅ On the INTO THE IMPOSSIBLE Podcast, they dive into the latest breakthroughs, myths, and the future of quantum tech beyond code cracking.
✅ Discover why the next quantum revolution might just start on your laptop—and how you can be part of it!

Conversation Starters for the Facebook Group

1. Brian Keating mentions that code breaking is currently the only area where quantum computers show dramatic progress. Do you think this focus on cryptography is justified, or should there be more emphasis on other potential applications? Why?

2. After learning about the rapid advancements in quantum computing highlighted by Brian Keating and Bob Wold, are you more excited or more concerned about the future of encryption and cybersecurity?

3. Brian Keating compares today's quantum computing revolution to the early days of personal computers in the 1980s. What parallels do you see between these two technological shifts, and how do you think society will adapt?

4. What are your thoughts on the idea shared by Bob Wold that quantum computing could tackle issues like cancer, climate change, and world hunger? Which potential application excites you the most and why?

5. Do you agree with Brian Keating that the biggest bottleneck for quantum computing isn't physics, but people who can develop and apply quantum circuits? How can we better encourage and train new talent in this field?

6. Has anyone in the group tried out the Quantum 101 course or similar quantum computing tools mentioned in the episode? Share your experience! Was it as accessible and exciting as Brian Keating described?

7. Brian Keating and Bob Wold talk about the ethical concerns of publishing encryption-breaking algorithms. Where do you stand on the open science vs. security debate in quantum tech?

8. How do you feel about Brian Keating’s statement that we are just at the beginning of discovering what quantum computers are truly good for, beyond code breaking? What new applications do you predict will emerge in the next decade?

9. Student 2 describes quantum physics as ‘mind blowing’ and surprisingly approachable. For those new to the field, what’s been your biggest challenge or surprise when learning about quantum computing?

10. Quantum Rings and similar platforms are democratizing access to quantum computing. How important is it for tools like these to be free and widely available? Can this accessibility lead to significant breakthroughs outside of elite research labs?

1/

Quantum computers aren’t just code-cracking machines—they might be the key to the next big leap.

2/

Most headlines focus on terrifying encryption breakthroughs. They miss the real revolution: quantum access is now democratized.

3/

Five years ago, only a handful could play with quantum circuits. Today, students are designing and running algorithms on their laptops… for free.

4/

What changed? Tools like Quantum Rings. They put qubits at our fingertips, not behind paywalls or lab doors.

5/

Just like home PCs in the ’80s, we have no idea what the killer app will be. We need hordes of tinkerers to even find out.

6/

Breakthroughs in chemistry, AI, energy, medicine? Possible—but only if tens of thousands get hands-on. The only obstacle is people.

7/

Quantum’s bottleneck isn’t hardware or physics. It’s curious minds who build, break, and invent.

8/

Get in early. Learn. Iterate. Quantum needs a million explorers, not just another security headline.

9/

We’re witnessing the dawn of computing—again. This time, don’t miss your chance to build something impossible.

🚀 Into the Impossible Podcast: New Episode Alert!

Sabine Hossenfelder & Quantum Computers

Hey Impossible Thinkers,

We’re thrilled to drop our latest episode where we dive headfirst into the real world of quantum computers—what they’re good for, what’s hype, and what’s just around the corner for the technology that’s changing the future right beneath our noses. Inspired by Sabine Hossenfelder’s viral video (almost half a million views in days!), we take a look behind the headlines—straight from our lab at UC San Diego.

🎧 In this episode, you’ll learn:

1. Why code-breaking is just the tip of the quantum iceberg
Quantum computers have a reputation for being cybersecurity’s nightmare. Brian Keating and Bob Wold unpack why that’s both true and far from the whole story 00:00:22.

2. How Google is accelerating the countdown to “Q Day”
What happens when the world’s biggest tech companies get involved? It’s not just about code-breaking speed—quantum supremacy could hit in just a few years! 00:00:16

3. Why quantum chemistry, material science, and optimization are the next frontier
Brian Keating explains why the revolution isn’t just in papers, it’s in the tools that’ll launch a new era of discovery—from drug design to sustainable batteries 00:05:10.

4. The new way to learn quantum coding for free—from your laptop!
Forget the days of clunky equipment. With Quantum Rings and the Quantum 101 course, anyone (yes, even you!) can start building algorithms and running circuits, free and easy 00:06:09.

5. The real bottleneck isn’t the science—it’s people
We don’t just need breakthroughs, we need a workforce of quantum creators. The episode breaks down how YOU could join thousands in shaping the future 00:10:58.

🤓 Fun Fact of the Episode:

Six weeks ago, one of our undergrad physics students had never touched a qubit. Now, they’re running Shor’s algorithm on a MacBook and scored a top-tier quantum internship in the Bay Area—all thanks to Quantum 101! 00:08:19

That’s a Wrap!

Brian Keating thinks Sabine is absolutely right on the risks—and believes the opportunities in quantum go way further. The next quantum revolution will be built by curious minds (like yours!) who jump in at the ground floor.

📢 Your Next Move:

Ready to peek into the quantum future?

• Listen to the new episode now!

• Check out Quantum 101 and see where your curiosity takes you!

• Tell us what you learned or built—we want to hear from you!

• Don’t forget to like, comment, and subscribe for more mind-bending science.

Stay impossible,
The INTO THE IMPOSSIBLE Podcast Team

10 Lessons Covered in the Event

1. Quantum Computing Basics

   • Lay the mathematical and software foundations required to begin working with quantum circuits and understand qubits.

2. Single Qubit Gates

   • Learn to manipulate individual qubits using gate operations and understand their basic impact on quantum states.

3. Entanglement Principles

   • Explore how qubits can be entangled, creating unique quantum correlations fundamental to quantum advantage.

4. Grover’s Search Algorithm

   • Understand Grover's algorithm for efficiently searching unsorted databases using quantum computation principles.

5. Quantum Fourier Transform

   • Study the quantum version of the Fourier transform, crucial for many quantum algorithms, including quantum phase estimation.

6. Shor’s Factoring Algorithm

   • Practice implementing Shor’s algorithm, the foundation of quantum codebreaking and a highlight in current quantum progress.

7. Noise and Error Mitigation

   • Address the problem of noise in quantum systems and learn basic strategies for error reduction and reliable computation.

8. Variational Algorithms

   • Discover hybrid algorithms that use both quantum and classical resources to solve optimization and simulation problems.

9. Quantum Error Correction

   • Learn principles behind protecting quantum information from errors, a key hurdle in building practical quantum computers.

10. Real-World Quantum Programming

    • Apply concepts by writing, running, and optimizing circuits on simulators and real quantum hardware from various vendors.

Ten Most Surprising and Useful Frameworks & Takeaways

1. Quantum Computing’s Perceived Single Utility: Code Breaking

• Brian Keating underscores that, as per Sabine Hossenfelder’s viral analysis, quantum computers are currently viewed as mainly effective for code breaking, specifically breaking encryption with Shor’s algorithm 00:00:06. However, this is not the only story.

2. Accelerated Timeline for Quantum Supremacy ("Q Day")

• Google’s recent advancements have moved the projected date of “quantum supremacy” up to 2029, shrinking the timeline for major quantum breakthroughs by several years 00:00:22, 00:04:30.

3. Dramatic Reduction in Quantum Resources Needed for Encryption Breaking

• Recent papers—one by Google, and one by a startup called Oratomic—suggest quantum machines need far fewer qubits (from 10 million down to about 500,000, or even 26,000 using neutral atom arrays) to break RSA encryption 00:00:58, 00:01:22. This is a radical speedup 00:01:38.

4. Ethical Debate Over Publishing Quantum Breakthroughs

• The pace of quantum progress is so rapid and its ramifications so serious that leading scientists like Scott Aaronson are questioning whether it’s responsible to make these breakthroughs public 00:02:03.

5. Shift in Quantum Computing Accessibility and Tooling

• Five years ago, running basic quantum circuits meant long queues for limited, noisy results. Now, with platforms like Quantum Rings, simulators on personal laptops can handle hundreds of qubits and millions of gate operations for free 00:03:04, 00:05:16.

6. Quantum Computing's Real-World Promise: Beyond Encryption

• Bob Wold projects a future where quantum computing leads to radical advances in medicine, battery technology, supply chain optimization, and ending world hunger—not just code breaking 00:03:27.

7. The Bottleneck is Talent, Not Physics

• According to Brian Keating, the central issue is the lack of trained people, not fundamental scientific or hardware barriers. There are only a few thousand capable quantum circuit designers today, but the field needs hundreds of thousands, even a million 00:10:58.

8. Free Quantum Education Resources (“Quantum 101”)

• The “Quantum 101” program by Quantum Rings offers free, self-paced, accessible education and real experimentation on quantum hardware or simulators for anyone, rapidly expanding the talent funnel 00:05:33, 00:06:14.

9. Real Student Impact

• Undergraduates, including freshmen, can now run industry-standard quantum algorithms (like Shor’s) on their own laptops within weeks—some have secured top internships directly as a result 00:08:19.

10. Open Infrastructure and Democratization

• Quantum Rings (and its “Open Quantum” suite) is working with over 250 universities worldwide, providing free credits and access to real quantum hardware—signaling a paradigm shift towards democratizing quantum development and unlocking unforeseen applications 00:09:10, 00:09:38.

Meta-Takeaway

As Brian Keating frames it: We’re in an “Apple II” moment for quantum computers—we don’t know all their eventual uses, and the biggest breakthroughs may come once far more people have hands-on access and imaginative application grows 00:11:42.

Social Media Clips from "The INTO THE IMPOSSIBLE Podcast: Sabine Hossenfelder Quantum Computers"

Clip 1

• Title: "Quantum Computing: The Code Breaking Race Heats Up"

• Timestamps: 00:00:00–00:03:10

• Caption:
  Quantum computers are advancing at a breathtaking pace. Brian Keating breaks down three groundbreaking papers released in a single week that slash qubit requirements and bring the threat of broken encryption years closer. From Google's secretive breakthroughs to new startups shaking up the quantum scene, discover why the debate isn't just about technology—but about the very future of digital security.

Clip 2

• Title: "A Quantum Leap: How Today's Students Are Building Tomorrow's Supercomputers"

• Timestamps: 00:03:10–00:06:10

• Caption:
  The revolution in quantum tooling is here. Brian Keating reveals how his undergraduates are already building and programming quantum computers, with free simulators that run hundreds of qubits right on their laptops. Learn how the barrier to entry is dropping—and why this matters for the next generation of quantum developers.

Clip 3

• Title: "Unlocking Quantum for Everyone: Free Tools and Courses Explained"

• Timestamps: 00:06:10–00:09:03

• Caption:
  Brian Keating and Bob Wold showcase Quantum 101 and the push to democratize quantum computing. From free, hands-on courses run by MIT experts to internships with major industry players, learn how anyone can start contributing to the next wave of technological breakthroughs—no PhD required.

Clip 4

• Title: "What Are Quantum Computers Good For? Beyond Code Breaking"

• Timestamps: 00:09:03–00:12:03

• Caption:
  Is code breaking really all quantum computers can do? Brian Keating makes the case for a future where quantum computers solve humanity’s toughest challenges, from curing cancer to ending world hunger. But the biggest bottleneck isn't physics—it's people. Discover why we need a quantum workforce explosion, and how you can be a part of it.

Clip 5

• Title: "A Call to Action: Join the Quantum Revolution Today"

• Timestamps: 00:09:38–00:12:30

• Caption:
  The quantum future is arriving faster than anyone imagined. Bob Wold and Brian Keating invite students and researchers to dive into free platforms, build real circuits, and prepare for a world transformed by quantum power. Think you can’t participate? Think again—quantum democratization starts now.