The New Quantum Era - innovation in quantum computing, science and technology

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• Quantum Book Launch with Yuval Boger 01.06.2026 54min

  Yuval Boger — Chief Commercial Officer of QuEra Computing and one of quantum's most prolific podcasters — joins Sebastian for a crossover episode that doubles as a working session between two people trying to make quantum computing comprehensible. They compare notes on writing books for non-physicists, debate how close neutral-atom systems are to genuine quantum utility, and dig into why the gap between physical and logical qubits is narrowing far faster than most public roadmaps suggest.
• Fault Tolerance for Quantum Inputs and Outputs with Matthias Christandl 25.05.2026 38min

  What happens to fault tolerance when a quantum computer's job is not to spit out a classical answer, but to produce a quantum state that gets sent somewhere else — to another core, another machine, or across a network? Mathias Christandl, professor at the University of Copenhagen and director of the Quantum for Life Center, walks Sebastian through a reframing of the fault tolerance theorem for quantum input and quantum output, and what that shift means for distributed quantum computing, channel capacities, and the practical path to useful quantum simulation in the life sciences.
• Philosophy of Physics Meets Quantum Engineering with Elise Crull 18.05.2026 42min

  What does philosophy of science actually *do* for quantum technology at the moment quantum mechanics is being asked to deliver? Elise Crull — historian, philosopher of physics, and 2025 APS Fellow — joins Sebastian to talk about how interpretive choices are quietly built into quantum hardware, why definitions of entanglement and decoherence matter for engineering, and what archival work on EPR, Grete Hermann, and Hertha Sponer reveals about the stories quantum computing tells itself today.
• The Quantum Control Stack with Niels Bultink 11.05.2026 37min

  Every quantum computer — superconducting, spin, trapped ion, or neutral atom — depends on a layer most people never see: the precisely timed electronics that play qubits like a microwave-frequency piano and read the answers back. Niels Bultink, co-founder and CEO of Qblox, joins Sebastian to explain why the quantum control stack has become a strategic bottleneck for scaling quantum hardware, and how a Delft spinout is building the picks-and-shovels of fault-tolerant quantum computing while expanding into the U.S. through a Boston headquarters, U.S. manufacturing in Massachusetts, and a partnership with Fermilab on the open-source QICK platform.
• Hardware-Faithful Digital Twins for Quantum Computing with Izhar Medalsy 04.05.2026 38min

  Quantum hardware iteration is gated by the simple fact that real QPUs are expensive, scarce, and noisy in ways that generic simulators don't capture. In this episode, Izhar Medalsy, co-founder and CEO of Quantum Elements, explains why the industry is still building "wooden models in the air tunnel" — and how hardware-faithful digital twins, scaled to a distance-7 rotated surface code with 97 physical qubits on AWS HPC, could give pulse engineers, circuit designers, and QEC decoder teams a faster, cheaper place to iterate.
• Are We Computing Quantum in the Wrong Base? with Ivan Deutsch 27.04.2026 45min

  Every commercial neutral-atom quantum computer today encodes information in just two energy levels of an atom that has many more — strontium has ten nuclear-spin levels, cesium has sixteen. Ivan Deutsch, one of the founding theorists of neutral-atom quantum computing, joins the podcast to ask whether binary is really the right base for quantum computation, and to make the case for spin cat codes: a fault-tolerant encoding that embeds a qubit inside the richer structure of a qudit, the way bosonic cat codes use microwave cavities. Along the way, Ivan traces three decades at UNM — from the earliest days of quantum information science to his role building Elevate Quantum, the only federally designated quantum Tech Hub in the United States.
• Quantum Chemistry's Classical Limits with Garnet Chan 20.04.2026 41min

  One of the most-cited arguments for near-term quantum advantage in chemistry just got a rigorous classical answer — from one of the world's leading quantum chemists. Garnet Chan's group at Caltech solved the FeMo-cofactor ground-state energy problem classically, to chemical accuracy, using tensor networks and coupled cluster methods. If you've heard that quantum computers are uniquely needed to simulate nitrogen fixation, this episode will sharpen — and complicate — that picture.
• Quantum Open Source with Will Zeng and Ziyaad Bhorat 17.04.2026 1t 2min

  Quantum computing is drawing billions in investment, but the open source software layer that could make it all work is falling through the cracks. Who fills that gap — and why should philanthropy care?
• Simulating Quantum Materials with Arnab Banerjee 07.04.2026 40min

  Can a quantum computer reproduce what happens when you fire neutrons at a magnetic crystal? Arnab Banerjee, the experimentalist who discovered the first signatures of a Kitaev quantum spin liquid, just proved it can — benchmarking IBM's Heron processor against real neutron scattering data from national laboratories. This is what quantum utility looks like when it's grounded in decades of experimental physics.
• Quantum Advantage Achieved with Dominik Hangleiter 01.04.2026 37min

  Has quantum advantage actually been achieved — or is the field still arguing over its own milestones? Dominik Hangleiter, one of the leading theorists working on quantum computational advantage, joins the podcast to make the case that it has, explain why so many physicists remain unconvinced, and map the path toward fault-tolerant, verifiable quantum advantage.
• Scaling Quantum Hardware Like Semiconductors with Matthijs Rijlaarsdam 23.03.2026 37min

  The quantum computing industry has been stuck at roughly 100 qubits for years — not because of physics, but because of wiring. Matthijs Rijlaarsdam, co-founder and CEO of QuantWare, explains how his company's 3D vertical chip architecture (VIO) could break through that ceiling to 10,000 qubits by 2028, and why the quantum industry needs to start thinking like the semiconductor industry if it wants to actually deliver on its promises.
• Engineering the Quantum Future with Brian Gaucher 16.03.2026 40min

  Ever wonder why quantum computing still feels like a "cool science experiment" instead of a deployable technology? After two decades building wireless standards and quantum systems at IBM, Brian Gaucher argues that engineering—not physics—has become the critical bottleneck holding back quantum technologies from real-world impact.
• Quantum Engineering with David Reilly and Tom Ohki 09.03.2026 48min

  Have you ever wondered what it takes to build computing systems that work at temperatures colder than outer space? David Reilly and Tom Ohki are tackling this exact challenge, leading a "special ops" team of engineers from their unique position at Emergence Quantum—the startup born from Microsoft's Station Q program. They're not just building quantum computers; they're creating the entire infrastructure ecosystem that will make scalable quantum computing possible.
• The Illinois Quantum Ecosystem with Harley Johnson 02.03.2026 39min

  What does it take to build the world's largest dedicated quantum technology park — on the site of a former steel mill? Harley Johnson is leading that effort, and the answer involves equal parts materials science, economic development, and a 30-year bet on quantum that's finally paying off.
• Quantum LDPC error correction with Larry Cohen and Paul Webster 26.02.2026 37min

  What if I told you that the number of qubits needed to break RSA encryption just dropped from over a million to around 100,000? That's exactly what researchers at Iceberg Quantum achieved by combining quantum low-density parity-check (QLDPC) error correction with algorithmic optimizations—potentially accelerating quantum cryptography timelines by years.
• Our Quantum Future with Evan Kubes 23.02.2026 38min

  Evan Kubes, co-founder of The Quantum Insider and Resonance, shares the unlikely origin story of building one of quantum's leading media platforms — and why he spent the last year making Our Quantum Future, a feature-length documentary premiering at APS March Meeting.
• Building a Quantum Ecosystem from Scratch with Martin Laforest 17.02.2026 42min

  What does it take to build a thriving quantum ecosystem from the ground up? Martin Laforest, physicist-turned-venture-capitalist at Quantacet, reveals how Quebec transformed a 1970s academic bet into a $400M quantum powerhouse—and why the industry's biggest misconception is thinking quantum computing is either a science problem or an engineering problem when it's clearly both.SummaryIn this conversation, Sebastian sits down with Martin Laforest, partner at Quantacet, Canada's quantum-only VC fund, to explore the messy realities of building quantum companies and ecosystems. Martin brings a rare perspective: PhD from Waterloo's Institute for Quantum Computing, eight years leading scientific outreach, a stint building a post-quantum cryptography startup with ex-BlackBerry executives, and now investing in the quantum future.This episode is for anyone trying to understand how quantum technology actually gets built—not the hype, but the infrastructure, the collaboration models, the government investment strategies, and the patience required. Whether you're technical or just curious about how transformative technologies emerge, Martin offers a grounded view of what's working, what's not, and why the quantum revolution looks more like slow, deliberate ecosystem building than overnight breakthroughs.What You'll LearnWhy quantum is both a science and engineering challenge and how the vacuum tube-to-transistor transition illuminates today's quantum journeyHow Quebec built a world-class quantum ecosystem starting from a 1970s university bet on condensed matter physics through to today's $400M provincial investmentThe infrastructure that matters: why Sherbrooke's six shared dilution fridges and quantum communication testbed represent a different collaboration modelWhat VCs actually look for in quantum startups beyond the technology—and why Martin believes early-stage investing is about building great companies, not just returnsThe three most dangerous misconceptions plaguing quantum technology (spoiler: it's not just about quantum computers)How regional quantum ecosystems should compete and collaborate with lessons from Netherlands, Chicago, and UK programsWhy fundamental research funding can't stop even as commercialization accelerates—and what happens when governments don't understand this balanceWhat "mutualized infrastructure" means in practice and why no single entity owning critical testbeds might be the secret sauceHow federal and provincial politics shape quantum strategy in Canada and what other countries can learn from itResources & LinksQuantacetInstitute for Quantum Computing (IQC)University of Sherbrooke Institute QuantiqueC2MI semiconductor fabrication facilityQuantumDELTAKey InsightsOn the science vs. engineering debate:"People ask if quantum computing is still a science problem or just engineering. It's both. Look at the vacuum tube to transistor transition—we needed new physics and new engineering. That's exactly where we are now."On ecosystem building:"Sherbrooke made a bet on condensed matter physics in the 1970s. Fifty years later, they have six dilution fridges available for rent and a quantum communication testbed owned by no one. That infrastructure patience is what builds real ecosystems."On VC philosophy:"Early-stage venture capital is about building great companies. The money is a byproduct. If you focus on the returns first, you'll make the wrong decisions every time."On common misconceptions:"The biggest myth is that quantum technology equals quantum computing. We have quantum sensors, quantum communications, post-quantum crypto—this is a multi-faceted industry, not a single magic box."On balancing research and commercialization:"You can't stop funding fundamental research just because commercialization is happening. The vacuum tube didn't kill physics research. We need both engines running or the whole thing stalls."Join the ConversationSubscribe to The New Quantum Era wherever you get your podcasts to hear more conversations with the people building quantum technology's future.
• Quantum consciousness with Joachim Keppler 09.02.2026 36min

  What if consciousness isn’t generated by the brain, but emerges from its interaction with a ubiquitous quantum field? In this episode, Sebastian Hassinger and theoretical physicist Joachim Keppler explore a zero‑point field model of consciousness that could reshape both neuroscience and quantum theory.SummaryThis conversation is for anyone curious about the “hard problem” of consciousness, quantum brain theories, and the future of quantum biology and AI. Joachim shares his QED‑based framework where the brain couples to the electromagnetic zero‑point field via glutamate, producing macroscopic quantum effects that correlate with conscious states. You’ll hear how this model connects existing neurophysiology, testable predictions, and deep questions in philosophy of mind.What You’ll Learn How a quantum field theorist ended up founding an institute for the scientific study of consciousness and building a rigorous, physics‑grounded framework for it. Why consciousness may hinge on a universal principle: the brain’s resonant coupling to the electromagnetic zero‑point field, not just classical neural firing. What macroscopic quantum phenomena in the brain look like, including coherence domains, self‑organized criticality, and long‑range synchronized activity patterns linked to conscious states. How glutamate, the brain’s most abundant neurotransmitter, could act as the molecular interface to the zero‑point field inside cortical microcolumns. Which concrete experiments could confirm or falsify this theory, from detecting macroscopic quantum coherence in neurotransmitter molecules to measuring glutamate‑driven biophoton emissions with a specific quantum “fingerprint.” Why Joachim sees the zero‑point field as a dual‑aspect “psychophysical” field and how that reframes classic philosophy‑of‑mind debates about qualia and the nature of awareness. What this perspective implies for artificial consciousness and whether future quantum computers or engineered systems might couple to the field and become genuinely conscious rather than merely simulating it. How quantum biology could offer an evolutionary path for consciousness, extending field‑coupling ideas from the human brain down to simpler organisms and bacterial signaling.Resources & LinksDIWISS Research Institute for the scientific study of consciousness “Macroscopic quantum effects in the brain: new insights into the neural correlates of consciousness” – Research article outlining the QED/zero‑point field model and its neurophysiological connections. “A New Way of Looking at the Neural Correlates of Consciousness” – Paper introducing the idea that the full spectrum of qualia is encoded in the zero‑point field. “The Role of the Brain in Conscious Processes: A New Way of Understanding the Neural Correlates of Consciousness” – Further develops the brain‑as‑interface, ZPF‑based frameworkHuman high intelligence is involved in spectral redshift of biophotonic activities in the brain - studies on glutamate‑linked emissions in brain tissue – Experiments that inform potential tests of the theory.Key Quotes or Insights “The brain may not produce consciousness; it may tune into it by coupling to the zero‑point field, like a resonant oscillator accessing a universal substrate of awareness.” “Conscious states correspond to macroscopic quantum patterns in the brain—highly synchronized, near‑critical dynamics that disappear when the field coupling breaks down in unconsciousness.” “Glutamate‑rich cortical microcolumns could be the molecular gateway to the zero‑point field, forming coherence domains that orchestrate neuronal firing from the bottom up.” “If we can engineer systems that replicate this field‑coupling mechanism, we might not just simulate consciousness—we might be building genuinely conscious artificial systems.” “Quantum biology could reveal an evolutionary continuum of field‑coupling, from simple organisms to humans, reframing how we think about life, intelligence, and mind.”
• Quantum Leadership with Nadya Mason 02.02.2026 45min

  What happens when a former elite gymnast with “weak math and science” becomes dean of one of the world’s most influential quantum engineering schools? In this episode of *The New Quantum Era*, Sebastian Hassinger talks with Prof. Nadya Mason about quantum 2.0, building a regional quantum ecosystem, and why she sees leadership as a way to serve and build community rather than accumulate power.Summary  This conversation is for anyone curious about how quantum materials research, academic leadership, and large‑scale public investment are shaping the next phase of quantum technology. You’ll hear how Nadya’s path from AT&T Bell Labs to dean of the Pritzker School of Molecular Engineering at UChicago informs her service‑oriented approach to leadership and ecosystem building.  The discussion spans superconducting devices, Chicago’s quantum hub strategy, and what it will actually take to build a diverse, job‑ready quantum workforce in time for the coming wave of applications.What You’ll LearnHow a non‑linear path (elite sports, catching up in math, early lab work) can lead to a career at the center of quantum science and engineering.Why condensed matter and quantum materials are the quiet “bottleneck” for scalable quantum computing, networking, and transduction technologies.How superconducting junctions, Andreev bound states, and hybrid devices underpin today’s superconducting qubits and topological quantum efforts.The difference between “quantum 1.0” (lasers, GPS, nuclear power, semiconductors) and “quantum 2.0” focused on sensing, communication, and computation.How the Pritzker School of Molecular Engineering and the Chicago Quantum Exchange are deliberately knitting together universities, national labs, industry, and state funding into a cohesive quantum cluster.Why Nadya frames leadership as building communities around science and opportunity, and what that means in a faculty‑driven environment where “nobody works for the dean.”Concrete ways Illinois and UChicago are approaching quantum education and workforce development, from REUs and the Open Quantum Initiative to the South Side Science Fair.Why early math confidence plus hands‑on research experience are the two most important ingredients for preparing the next generation of quantum problem‑solvers.Resources & Links  Pritzker School of Molecular Engineering, University of Chicago – Nadya’s home institution, pioneering an interdisciplinary, theme‑based approach to quantum, materials for sustainability, and immunoengineering.Chicago Quantum Exchange – Regional hub connecting universities, national labs, and industry to build quantum networks, workforce, and commercialization pathways.South Side Science Fair (UChicago) – Large‑scale outreach effort bringing thousands of local students to campus to encounter science and quantum concepts early.Key Quotes or Insights  “A rainbow is more beautiful because I understand the fraction behind it”—how physics deepened Nadya’s sense of wonder rather than reducing it.“In condensed matter, the devil is in the material—and the interfaces”—why microscopic imperfections and humidity‑induced “schmutz” can make or break quantum devices.“Quantum 1.0 gave us lasers, GPS, and nuclear power; quantum 2.0 is about using quantum systems to *process* information through sensing, networking, and computing.”“If you want to accumulate power, academia is not the place—faculty don’t work for me. Leadership here is about building community and creating opportunities.”“If we want to lead in quantum as a country, we have to make math skills and real lab experiences accessible early, so kids even know this world exists as an option.”Calls to Action  Subscribe to The New Quantum Era and share this episode with a colleague or student who’s curious about quantum careers and leadership beyond the usual narratives.If you’re an educator or program lead, explore ways to bring hands‑on research experiences and accessible math support into your classroom or community programs.If you’re in industry, academia, or policy, consider how you or your organization can plug into regional quantum ecosystems like Chicago’s to support training, internships, and inclusive hiring.
• Democratizing Quantum Venture Investing with Chris Sklarin 26.01.2026 33min

  Your host, Sebastian Hassinger, talks with Alumni Ventures managing partner Chris Sklarin about how one of the most active US venture firms is building a quantum portfolio while “democratizing” access to VC as an asset class for individual investors. They dig into Alumni Ventures’ co‑investor model, how the firm thinks about quantum hardware, software, and sensing, and why quantum should be viewed as a long‑term platform with near‑term pockets of commercial value. Chris also explains how accredited investors can start seeing quantum deal flow through Alumni Ventures’ syndicate.Chris’ background and Alumni Ventures in a nutshellChris is an MIT‑trained engineer who spent years in software startups before moving into venture more than 20 years ago.Alumni Ventures is a roughly decade‑old firm focused on “democratizing venture capital” for individual investors, with over 11,000 LPs, more than 1.5 billion dollars raised, and about 1,300 active portfolio companies.The firm has been repeatedly recognized as a highly active VC by CB Insights, PitchBook, Stanford GSB, and Time magazine.How Alumni Ventures structures access for individualsMost investors come in as individuals into LLC‑structured funds rather than traditional GP/LP funds.Alumni Ventures always co‑invests alongside a lead VC, using the lead’s conviction, sector expertise, and diligence as a key signal.The platform also offers a syndicate where accredited investors can opt in to see and back individual deals, including those tagged for quantum.Quantum in the Alumni Ventures portfolioAlumni Ventures has 5–6 quantum‑related investments spanning hardware, software, and applications, including Rigetti, Atom Computing, Q‑CTRL, Classiq, and quantum‑error‑mitigation startup Qedma/Cadmus.Rigetti was one of the firm’s earliest quantum investments; the team followed on across multiple rounds and was able to return capital to investors after Rigetti’s SPAC and a strong period in the public markets.Chris also highlights interest in Cycle Dre (a new company from Rigetti’s former CTO) and application‑layer companies like InQ and quantum sensing players.Barbell funding and the “3–5 year” viewChris responds to the now‑familiar “barbell” funding picture in quantum— a few heavily funded players and a long tail of small companies—by emphasizing near‑term revenue over pure science experiments.He sees quantum entering an era where companies must show real products, customers, and revenue, not just qubit counts.Over the next 3–5 years, he expects meaningful commercial traction first in areas like quantum sensing, navigation, and point solutions in chemistry and materials, with full‑blown fault‑tolerant systems further out.Hybrid compute and NVIDIA’s signal to the marketChris points to Jensen Huang’s GTC 2025 keynote slide on NVIDIA’s hybrid quantum–GPU ecosystem, where Alumni Ventures portfolio companies such as Atom Computing, Classiq, and Rigetti appeared.He notes that NVIDIA will not put “science projects” on that slide—those partnerships reflect a view that quantum processors will sit tightly coupled next to GPUs to handle specific workloads.He also mentions a large commercial deal between NVIDIA and Groq (a classical AI chip company in his portfolio) as another sign of a more heterogeneous compute future that quantum will plug into.Where near‑term quantum revenue shows upChris expects early commercial wins in sensing, GPS‑denied navigation, and other narrow but valuable applications before broad “quantum advantage” in general‑purpose computing.Software and middleware players can generate revenue sooner by making today’s hardware more stable, more efficient, or easier to program, and by integrating into classical and AI workflows.He stresses that investors love clear revenue paths that fit into the 10‑year life of a typical venture fund.University spin‑outs, clustering, and deal flowAlumni Ventures certainly sees clustering around strong quantum schools like MIT, Harvard, and Yale, but Chris emphasizes that the “alumni angle” is secondary to the quality of the venture deal.Mature tech‑transfer offices and standard Delaware C‑corps mean spinning out quantum IP from universities is now a well‑trodden path.Chris leans heavily on network effects—Alumni Ventures’ 800,000‑person network and 1,300‑company CEO base—as a key channel for discovering the most interesting quantum startups.Managing risk in a 100‑hardware‑company worldWith dozens of hardware approaches now in play, Chris uses Alumni Ventures’ co‑investor model and lead‑investor diligence as a filter rather than picking purely on physics bets.He looks for teams with credible near‑term commercial pathways and for mechanisms like sensing or middleware that can create value even if fault‑tolerant systems arrive later than hoped.He compares quantum to past enabling waves like nanotech, where the biggest impact often shows up as incremental improvements rather than a single “big bang” moment.Democratizing access to quantum ventureAlumni Ventures allows accredited investors to join its free syndicate, self‑attest accreditation, and then see deal materials—watermarked and under NDA—for individual investments, including quantum.Chris encourages people to think in terms of diversified funds (20–30 deals per fund year) rather than only picking single names in what is a power‑law asset class.He frames quantum as a long‑duration infrastructure play with near‑term pockets of usefulness, where venture can help investors participate in the upside without getting ahead of reality.