Counting Qubits, Not Calories: A November Harvest to Be Thankful For, Quantum Doom Clock, November 2025

GM frens, this is the Quantum Doom Clock with Colton Dillion and Rick Carback, the founders of Quip Network, the world’s shared quantum computer. We’d like to extend a heartfelt welcome to all our new readers who discovered us this month, likely through a variety of viral tweets sharing our doomsday model. It’s possible we even got in front of Vitalik himself as he updated his timeline at Devconnect to match our Q-Day predictions. It’s a good month to start following along because we reviewed a record number of quantum stories this month, over twice as many as October. Collective awareness is clearly growing!

This November, as we gather around virtual tables filled with cranberry sauce and quantum white papers, we pause not to lament the clock’s ticking but to give thanks for the quiet revolutions unfolding in dilution refrigerators and fab ovens around the world. Every breakthrough in coherence, scaling, and error correction was a dish prepared by generations of researchers for whom we can’t express enough gratitude. Let’s eat well, think deeply, and keep building to serve the future.

This month especially we’d like to highlight the Quantum Index Report 2025 from the MIT Sloan Management School. This report primarily tracks the growth of Quantum in corporate life, noting that it now receives regular mention in company documents and earnings calls. The report itself contains a number of insights and data about how business is taking quantum seriously and indicates a massive future for growth.

From Lab to Life: Quantum Computing Embedded in Airports, Datacenters, and Beyond

The era of isolated quantum experiments is over, and the focus has shifted decisively from raw qubit counts to performance, reliability, and enterprise integrations featuring local deployments:

Open Compute Project (OCP) has launched a workstream to standardize the integration of quantum computers into classical datacenters, formalizing IBM’s real-world deployment of a 20-qubit system alongside HPC infrastructure
IBM and Cisco are building the backbone of a quantum internet capable of linking distributed fault-tolerant processors, targeting trillions of quantum gates for breakthroughs in materials and drug discovery
O’Hare Airport installed an IBM System One complete with a dilution refrigerator to demystify quantum tech for the public
NTT and OptQC are pioneering a room-temperature optical quantum computer targeting one million qubits by 2030, eliminating cryogenic constraints and advancing Japan’s quantum industrialization goals.
IonQ and Clemson solved large-scale job shop scheduling on 97-qubit hardware using a novel iterative QAOA that avoids deep circuits.
Harvard and MIT, alongside QuEra Computing, demonstrated the first integrated fault-tolerant quantum system using 448 neutral-atom qubits, successfully merging physical entanglement, logical operations, and below-threshold error correction in a single scalable platform.
Conductor Quantum and SemiQon partnered for high-fidelity silicon spin qubit fabrication with scalable CMOS-compatible control systems
Amazon Braket now offers Europe’s first trapped-ion quantum system (AQT’s IBEX Q1) with localized data residency, signaling a global shift toward quantum-as-a-service
IBM’s Qiskit Runtime now enables utility-scale dynamic circuits with real-time classical feedback, removing static circuit limitations.
AWS Quantum Technologies and Imperial College London have deployed quantum simulations of high-dimensional PDEs and the Fokker–Planck equation to model nonlinear fluid dynamics.
DARPA has selected 11 quantum companies to validate fault-tolerant architectures for utility-scale quantum operation by 2033.
Even China and India are accelerating: China Telecom launched global access to its Tianyan-287 superconducting quantum computer, while India’s National Quantum Mission is establishing chip fabrication hubs at IIT Bombay and IISc Bangalore.

Quantum computers continue to arrive at large corporations and government departments and we are now seeing the results of that starting to roll in, so it is only a matter of time before we see them as a staple in workplaces around the world, and perhaps even eventually in personal devices.

Beyond Isolation: Resolving Decoherence with Material Science and Network Design

Researchers managed a string of announcements this month with:

the development of erbium-based molecular qubits that operate at telecom wavelengths and seamlessly bridge quantum processors with existing fiber-optic infrastructure
a demonstration of quantum key distribution and private communication between 18 networked nodes
a massive improvement to 2D transmon qubits on high-resistivity silicon substrates which achieved quality factors exceeding 10⁷ and extending coherence into the millisecond range
a granular aluminum gralmonium qubits that defy magnetic field limitations by suppressing spin-related decoherence through spin freezing.
discovery of non-Markovian noise effects in multi-qubit systems, revealing how environmental memory distorts entanglement decay beyond standard models

These advances are representative of a broader trend showing that coherence is no longer a constraint of cryogenic isolation but an outcome of material design, qubit architecture, and topological control. Not to be left out, other institutions have been hacking away at similar problems for long-distance coherence:

University of Chicago’s Tian Zhong demonstrated coherence times that can support 2,000-km quantum links using a novel quantum memory crystal that overcomes optical signal loss. This is 200 times farther than previous limits.
Heriot-Watt researchers built a reconfigurable eight-user entanglement router using off-the-shelf optical fiber, demonstrating practical, deployable quantum networking
Oxford executed its first teleportation of quantum data between independent processors, successfully transmitting Grover’s algorithm and confirming that quantum networks are evolving from point-to-point links into multi-node systems.
These developments are further amplified by the integration of hybrid interfaces, such as the Karlsruhe Institute of Technology’s cryogenic optical memory linked to superconducting qubits, creating a multi-platform quantum fabric.

Meanwhile, noise characterization and error mitigation are becoming foundational to system design:

Johns Hopkins APL and University researchers unveiled a high-fidelity noise-mapping framework that pinpoints error sources with unprecedented precision, enabling targeted error mitigation for scalable fault-tolerant systems
In photonic systems, Quantum Pulse Ventures achieved room-temperature coherence extension via ultrafast optical pulse shaping, minimizing phase noise and photon loss
Chinese researchers achieved 1,000-fold photonic computing gains via low-loss waveguides
Quantum Art also demonstrated 10X circuit depth compression using all-to-all gates simulated on CUDA-Q
Ecole nationale Supérieure d’Informatique’s affine abstractions slashed SWAP gate overhead by leveraging mathematical symmetries in qubit connectivity
Zhaohui Yang’s Canopus framework integrated modern quantum instruction sets directly into routing, boosting circuit fidelity by up to 35%

This is a huge amount of research demonstrating progress across multiple simultaneous axes affecting horizontal scaling, data persistence, noise mitigation, and more, all signaling a maturing technology paradigm where coherence, communication, and computational efficiency are mutually reinforcing factors instead of isolated achievements.

The New Quantum Manufacturing Stack: EDA, Couplers, and Cryogenic Control

Manufacturing and infrastructure are fast becoming the new frontiers of scaling. IQM’s €40 million investment to double its Finnish production capacity now enables the annual manufacturing of over 30 superconducting quantum systems. This comes with better tooling, with Nanoacademic Technologies and Kothar Computing launching the first Quantum Electronic Design Automation (EDA) suite and, within days of that announcement, Keysight Technologies unveiled its Quantum System Analysis EDA platform. These EDA tools will be transforming chip development from physics-heavy trial-and-error into a repeatable, engineering-driven workflow.

The foundation of this shift is cemented by hardware innovations that dramatically reduce complexity and cost, which continue apace. Quantum Pulse Ventures’ directional coupler slashes qubit requirements by 90%, cutting system costs by up to $900 million per unit. AIST’s novel niobium fabrication process enables ultra-low-power superconducting circuits for qubit interfaces, achieving critical currents as low as 10 µA at ~10 mK. YQuantum’s miniaturized cryogenic systems will deliver scalable, high-fidelity control, and will help with solving one of quantum’s most persistent thermal bottlenecks.

The commercial viability of quantum systems also continues to receive further validation. Xanadu’s $3.6 billion SPAC merger with Crane Harbor Acquisition Corp secures nearly $500 million to accelerate photonic hardware development. Meanwhile USTC deployed the world’s first commercially operational neutral-atom quantum computer with 256 high-fidelity qubits. Further, IonQ reported a record revenue surge and Rigetti’s aggressive roadmap toward 1,000+ qubits by 2027, joining many of the other aggressive manufacturer estimates from these last few months, further underscoring that quantum computing is no longer an experimental pursuit.

Hardware-Integrated Quantum Error Correction Enters the Mainstream

A wave of hardware-driven breakthroughs is continuing to improve quantum error correction. Quantinuum’s Helios quantum computer achieved a record 99.9975% 1-qubit fidelity and enabling 48 logical qubits via its Guppy language, while IBM’s Nighthawk and Loom chips pushed computational complexity 30% beyond Heron by embedding fault-tolerant components directly into the hardware stack. Architectural improvements are not limited to superconducting platforms: IonQ’s room-temperature trapped-ion system achieved a 13:1 error correction overhead ratio. IQM’s Halocene platform introduced modular hardware explicitly engineered for scalable error mitigation.

On the error correction side, NVIDIA’s NVQLink is enabling real-time error correction by tightly coupling GPUs with quantum processors through CUDA-Q, partnering with nine U.S. national labs to accelerate classical decoding at scale. University of Tokyo’s novel QLDPC codes, combined with concatenated Steane codes and qudits, achieve constant space and polylogarithmic time overhead that reduces fault-tolerance overhead by up to 40% compared to traditional qubit-based approaches. Harvard and Princeton’s 448-atom neutral-atom arrays and Google’s dynamic surface codes enable real-time error detection and suppression below a critical threshold, while NTT and OptQC’s optical quantum collaboration leverages IOWN infrastructure to embed error correction into photonic communication from the start, targeting one million qubits by 2030 without cryogenic constraints.

The final piece of this new paradigm is algorithmic co-design: Cornell’s Multi-Core Circuit Decoder treats each logical gate as an independent decoding module, explicitly modeling correlated errors from entangling operations. This is complemented by the framework of quantum magic propagation via the bipartite magic gauge, which now allows researchers to predict where non-Clifford resources emerge in circuits, enabling targeted resource allocation. Together, these advances signal a new era: fault-tolerant quantum computing is no longer a distant goal but an engineered reality, built from the qubit up.

Quantum-Resistant Cryptographic Infrastructure Emerges as Global Priority

Saudi Aramco’s deployment of Pasqal’s 200-qubit system triggered alarms over quantum threats to blockchain, and China’s Hanyuan-1 secured an export order to Pakistan. This signals that state-backed quantum capabilities are becoming operational tools that are beginning to have geopolitical implications. These moves reflect a continuing global pivot where quantum advantage is no longer treated like a distant threat but an active strategic domain

The U.S. Congress introduced new bipartisan legislation to mandate federal agencies adopt post-quantum cryptography, and the Pentagon has elevated quantum sensing and secure communication to core battlefield capabilities, accelerating partnerships with national labs and startups. As far as tangible progress, TELUS integrated Palo Alto Networks’ post-quantum cryptography into its enterprise VPN service, offering protection against harvest-now-decrypt-later attacks and researchers have successfully embedded Dilithium and FALCON into a Raspberry Pi-based IoT-blockchain system running Ethereum’s Proof-of-Stake, showing that quantum-resistant signatures can function on low-power edge devices.

Simulating Many-Body Physics: Ion Traps, Waveguides, and Superconductors Unite

Simulation plays a critical role in Quantum development, providing a critical validation layer, ensuring algorithms can be tested at scales that mirror real-world hardware. Most notably, this month Jülich and NVIDIA created record-breaking 50-qubit quantum computer simulation on the JUPITER exascale system, surpassing their prior 48-qubit record from 2022 and demonstrating unprecedented scaling in quantum simulation capabilities.

Meanwhile, at Universität Heidelberg, Christof Wetterich and colleagues at Universität Heidelberg pioneered a groundbreaking approach to quantum simulation by leveraging classical electromagnetic waveguides to replicate the dynamics of multi-qubit quantum systems. This innovation circumvents the scalability bottlenecks of conventional quantum processors by using deterministic, room-temperature waveguide networks to emulate entanglement and coherent evolution, effectively turning classical wave physics into a programmable quantum simulator.

Quantum computers are also doing their fair share of simulating. Faisal Alam, Jan Lukas Bosse, Ieva Čepaitė, and their team achieved a landmark in quantum simulation by performing a programmable digital simulation of the 2D Fermi-Hubbard model on a 72-qubit superconducting quantum processor. This breakthrough enabled the first experimental observation of magnetic polaron formation and dynamical symmetry breaking in strongly correlated electron systems at scales unattainable by classical supercomputers. The team leveraged high-fidelity gate operations and error-mitigated readout techniques to maintain coherence across the lattice, demonstrating that quantum hardware has now crossed a critical threshold in simulating condensed matter phenomena with predictive accuracy.

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The Quantum Doom Clock is brought to you by Richard Carback and Colton Dillion, the cofounders of Quip Network

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