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Institute for Quantum Computing

The Institute for Quantum Computing (IQC) is an interdisciplinary research institute at the University of Waterloo in Waterloo, Ontario, Canada, dedicated to advancing quantum information science and technology through collaborative efforts among physicists, mathematicians, computer scientists, engineers, and chemists. Established in 2002 with visionary funding from Mike and Ophelia Lazaridis, alongside support from the Government of Canada and the University of Waterloo, IQC has grown into one of the world's leading hubs for quantum research, fostering innovations in quantum computing, communication, sensing, and materials. IQC's mission emphasizes groundbreaking , training, , and commercialization to realize the potential of quantum technologies for , powerful , and precise . The institute houses over 350 across multiple departments, supported by state-of-the-art facilities including the Mike & Ophelia Lazaridis Quantum-Nano Centre, which enables nanofabrication and characterization of quantum devices. Key research areas include , algorithms, , , optical quantum processing, ultracold atoms, and trapped ions, with notable projects such as developing trapped-ion quantum computers, quantum sensors for detecting , and systems for ultra-secure networks. Under founding executive director (2002–2017), who pioneered protocols, IQC established its global reputation; today, it is led by executive director Norbert Lütkenhaus, a specializing in quantum communication. The institute's impact extends to the economy, supporting approximately 650 jobs in quantum businesses in the region, with employment growing by about 10% every two years since 2021, and training thousands of students who contribute to over 3,000 published papers in the field.

History and Founding

Establishment

The Institute for Quantum Computing (IQC) was established in 2002 at the University of Waterloo through the vision and collaboration of Mike and Ophelia Lazaridis, founders' involvement via Mike Lazaridis as founder of Research In Motion (now BlackBerry), and David Johnston, then-president of the university. This founding marked a pivotal moment in advancing quantum research in Canada, with the Lazaridis family providing an initial private investment exceeding $100 million, which catalyzed further support from government and institutional sources to build foundational infrastructure. The primary motivation behind the IQC's creation was to position as a global leader in , leveraging the emerging potential of quantum technologies to drive innovation and . The Lazaridis family, inspired by the transformative possibilities of , sought to create a hub that would harness interdisciplinary expertise from fields including physics, , , , and chemistry, fostering breakthroughs that traditional computing paradigms could not achieve. This approach was designed to integrate theoretical insights with practical applications, addressing key challenges in information processing at the quantum scale. In its early years, the IQC began with a small cadre of researchers and rapidly expanded to define core research themes in processing, such as quantum communication, computing, and sensing. This initial phase laid the groundwork for collaborative projects that emphasized scalable , drawing on the university's strengths in multiple disciplines to pioneer advancements in quantum algorithms and . By focusing on these foundational areas, the institute quickly established itself as a nexus for quantum innovation, setting the stage for broader impacts in science and technology.

Key Milestones and Expansion

In 2008, the Institute for Quantum Computing relocated its operations to the newly constructed Research Advancement Centre (RAC) on the University of Waterloo's north campus, providing a dedicated space for expanding research activities. This move marked a significant infrastructural upgrade from previous facilities, enabling greater collaboration and accommodating the institute's growing team of researchers. Subsequent expansions in the following years included the occupation and development of additional space in the adjacent Research Advancement Centre 2 (RAC 2) around 2010, which further supported interdisciplinary quantum projects and industry partnerships. A pivotal advancement occurred in 2012 with the opening of the Mike & Ophelia Lazaridis Quantum-Nano Centre (QNC), a state-of-the-art facility spanning 26,000 square meters and designed to house advanced quantum and laboratories. Funded in part by a $100 million donation from Mike and Ophelia Lazaridis specifically for the building, this center integrated the institute's efforts with the Waterloo Institute for , fostering synergies in and device fabrication. By the early , cumulative donations from the Lazaridis family to the institute and related quantum initiatives at the exceeded $120 million, including initial endowments and ongoing support that bolstered operational scaling. By 2015, the institute had expanded to encompass nearly 200 researchers, including over 25 core faculty members affiliated across six departments such as physics, , , , and systems design engineering. This growth reflected the institute's broadening scope, with key milestones including the establishment of interdisciplinary graduate programs in leading to MMath, , MASc, and degrees, which enrolled over 100 students by that year and trained the next generation of quantum experts. These developments solidified the institute's position as a global leader in quantum research, driven by strategic funding and infrastructural investments.

Organization and Leadership

Administrative Structure

The Institute for Quantum Computing (IQC) operates as a multidisciplinary scientific research institute affiliated with the University of Waterloo, drawing together expertise from multiple departments across the faculties of Science, Mathematics, and Engineering. This structure spans key areas such as Physics and Astronomy, Electrical and Computer Engineering, Applied Mathematics, Chemistry, and Computer Science, enabling cross-disciplinary collaboration on quantum information science. Governance at the IQC is directed by an who oversees daily operations and strategic initiatives, complemented by endowed research chairs—such as Canada Research Chairs and Canada Excellence Research Chairs—held by leading faculty to advance specialized . An advisory board and executive committee provide oversight on long-term planning, , and partnerships, ensuring alignment with institutional goals and external funding priorities. The IQC supports a vibrant of over 400 , faculty, and students as of 2025, fostering interdisciplinary working groups organized around core pillars including , communication, and sensing. These groups facilitate collaborative projects, shared infrastructure access, and professional development, with approximately 30 faculty members leading efforts alongside postdoctoral and graduate students.

Prominent Figures and Governance

The Institute for Quantum Computing (IQC) was established through the visionary philanthropy of Mike and Ophelia Lazaridis, who provided an initial donation of $33.3 million in 2002 to create the institute at the , recognizing the transformative potential of . Their ongoing commitment has exceeded $120 million in total contributions, supporting infrastructure such as the Mike & Ophelia Lazaridis Quantum-Nano Centre, and continues through Quantum Valley Investments, a fund they co-founded with Doug Fregin in 2013 to commercialize quantum technologies and foster strategic growth. Leadership at IQC has evolved with key figures driving its direction. Raymond Laflamme served as the founding Executive Director from 2002 until 2017, pioneering research during the institute's early years; he passed away in June 2025. David Fransen served as Executive Director in an administrative capacity from 2006 to 2008, bringing expertise from federal public service to enhance operational and partnership development. As of 2025, Norbert Lütkenhaus holds the position of Executive Director, appointed in 2022, where he oversees research strategy and integration of quantum technologies, drawing on his expertise in . Among IQC's notable faculty, Michele Mosca stands out for his foundational role as co-founder and his pioneering work in , including the development of quantum-safe algorithms to address threats from quantum computers. As a professor in the Department of and Optimization, Mosca also contributes to ethical considerations in quantum through industry collaborations. Governance of IQC is integrated within the University of Waterloo's structure, with oversight provided by the university's Board of Governors, which manages institutional property, revenues, business conduct, and strategic priorities across all affiliates, including research institutes like IQC. External partnerships, such as those with the and Quantum Valley Investments, provide additional ethical and strategic guidance, ensuring alignment with national security standards and responsible innovation in quantum technologies.

Research Focus

Quantum Computing and Algorithms

The Institute for Quantum Computing (IQC) conducts extensive theoretical and experimental research on quantum processors, focusing on scalable platforms that enable fault-tolerant quantum computation. Researchers at IQC explore diverse modalities, including trapped ions, superconducting circuits, and photonic systems, to develop architectures capable of supporting error-corrected logical qubits. This work addresses key challenges in quantum , such as qubit connectivity, coherence times, and integration with control electronics, aiming to transition from noisy intermediate-scale quantum devices to reliable, large-scale systems. A prominent effort at IQC involves the development of trapped-ion quantum computers led by Crystal Senko's Trapped Ion Quantum Control Lab. This group utilizes ions confined in traps to create modular quantum processors, emphasizing scalable architectures that incorporate error-corrected s through high-fidelity entangling gates. In 2023, Senko's team demonstrated native qudit entangling gates using light-shift techniques that minimize motional errors, achieving gate fidelities up to 99.6% for s (d=2) and paving the way for scalable modular architectures. The lab also investigates qudits—higher-dimensional quantum states encoded in ion energy levels—to enhance computational density and efficiency in error-corrected systems, potentially reducing the overhead required for logical operations. Senko holds the in Trapped Ion Quantum Computing, underscoring IQC's commitment to this platform as a leading candidate for practical quantum processors. IQC researchers implement quantum error correction codes, such as surface codes, across multiple hardware platforms to mitigate decoherence and gate errors in quantum processors. In superconducting systems, the Superconducting Quantum Devices Group, led by Adrian Lupascu, fabricates Josephson junction-based qubits and resonators, researching scalable platforms suitable for quantum error correction such as surface codes. For photonic implementations, IQC's Quantum Photonics Laboratory, led by Thomas Jennewein, develops integrated optical circuits and single-photon sources for quantum communication and potential computing applications. These efforts, informed by theoretical advances in the Quantum Error Control group formerly led by Raymond Laflamme, include techniques like randomized compiling to suppress coherent errors, enabling logical qubits with exponentially improved lifetimes compared to physical qubits. IQC's research on quantum algorithms emphasizes fault-tolerant designs for optimization and simulation tasks, integrating hardware demonstrations with theoretical frameworks to ensure scalability. In the Quantum Information and Computation Theory Group, led by researchers like Luke Schaeffer, algorithms for quantum optimization—such as variational quantum eigensolvers adapted for noisy —are developed to solve combinatorial problems with quadratic speedups over classical methods, while prioritizing fault-tolerant variants that use error-corrected gates. For quantum , IQC teams employ Trotterized algorithms on trapped-ion and superconducting platforms to model molecular Hamiltonians, advancing benchmarks for fault-tolerant quantum . Recent work in the Quantum Software Group, under Michele Mosca, optimizes these algorithms for fault-tolerant execution, incorporating error mitigation to run optimization routines on current while projecting full fault tolerance with 1,000 logical qubits. Additionally, IQC researchers have proposed quantum algorithms for accelerating generative models, such as sampling from Boltzmann distributions for optimization in , demonstrating potential exponential advantages in fault-tolerant regimes.

Quantum Communication and Sensing

Researchers at the Institute for Quantum Computing (IQC) have advanced (QKD) systems to enable ultra-secure communication channels resistant to through the principles of quantum mechanics. In collaboration with the Quantum Photonics Lab led by Thomas Jennewein, a team including Katanya Kuntz developed a portable QKD demonstration utilizing single- sources and advanced from Excelitas Technologies, allowing secure over fiber-optic networks without detection of interception. This implementation addresses practical challenges in transitioning QKD from laboratory settings to real-world applications, such as secure data transport across urban or hostile environments, where fiber-optic limitations typically restrict distances to a few hundred kilometers due to loss. To overcome fiber-optic range constraints, IQC contributes to satellite-based QKD through the Quantum EncrYption and Science Satellite (QEYSSat) mission, coordinated by Katanya Kuntz as Science Team lead. As of 2025, QEYSSat, a low-Earth orbit satellite developed in partnership with the Canadian Space Agency, remains in development with a planned launch in 2026; it will feature a quantum receiver and transmitter designed to exchange quantum-encoded photons with ground stations, demonstrating QKD over global distances for enhanced network security. The mission focuses on studying quantum links in space, enabling the creation of secure keys for encryption that cannot be compromised by classical or quantum attacks without alerting users. In quantum sensing, IQC researchers have pioneered applications for medical diagnostics, particularly in detecting age-related macular degeneration (AMD) early through quantum light properties. Collaborating with the University of Waterloo's School of Optometry and Vision Science, a team led by Dusan Sarenac, along with Andrew Silva, David Cory, and Dmitry Pushin, developed a device using entangled polarized patterns that healthy eyes can distinguish but degenerating maculas cannot. This quantum-enhanced leverages vectorial profiles to identify subtle vision impairments, potentially improving treatment outcomes by enabling non-invasive, early-stage detection. The approach, detailed in a study published in the Proceedings of the , exploits quantum correlations in for precision beyond classical . IQC's quantum-safe cryptography initiatives emphasize post-quantum algorithms to protect against threats from future quantum computers capable of breaking current standards. Under the leadership of Michele Mosca, a founding director and professor at IQC, efforts include developing and promoting lattice-based and other mathematically robust protocols secure against both classical and quantum adversaries. These initiatives, supported by programs like CryptoWorks21 which Mosca co-founded, focus on training and transitioning cryptographic systems to quantum-resistant methods, such as those standardized by NIST. IQC also hosts the annual /IQC Quantum Safe Cryptography Conference to advance global standards and collaboration on post-quantum solutions.

Facilities and Infrastructure

Major Buildings

The Institute for Quantum Computing (IQC) is primarily housed in the Mike & Ophelia Lazaridis Quantum-Nano Centre (QNC), a five-storey facility spanning 285,000 square feet that opened in September 2012 on the University of Waterloo campus. This building is shared with the Waterloo Institute for Nanotechnology and features advanced architectural design to support quantum research, including vibration isolation (less than 3 µm deflection per second), precise temperature control (±0.1°C), humidity regulation (45% ±3%), low acoustic levels (NC-30), and shielding against radiofrequency interference and electromagnetic fields (less than 1 mG peak-to-peak). The QNC's layout organizes IQC and nanotechnology spaces above a shared podium that includes metrology labs, fostering interdisciplinary collaboration while providing dedicated areas for quantum computing experiments. Prior to the QNC's completion, IQC operations expanded into the Research Advancement Centres (RAC I and II) in the University of Waterloo's David Johnston Research and Technology Park, with the move to RAC I occurring in May 2008. RAC I, located at 475 Wes Graham Way, covers 10,000 square feet and includes dedicated office and lab spaces tailored for quantum information science. Adjacent to it, RAC II at 485 Wes Graham Way adds 70,000 square feet of collaborative research space, supporting industry-academia partnerships and technology development in a park setting that enhances accessibility for external collaborators. Together, these centres accommodate IQC's core administrative and experimental activities, with RAC II emphasizing quiet labs for sensitive quantum device work. The Quantum Nano-Fabrication and Characterization Facility (QNFCF) is integrated across these buildings, operating primarily within the QNC's approximately 8,000 square foot environment classified to ISO 4, 5, and 6 standards, alongside satellite labs in RAC I and II. This distributed setup enables seamless nanofabrication for quantum devices while leveraging the distinct locational advantages of the campus-based QNC for foundational research and the technology park's RAC facilities for applied and commercialization-oriented operations.

Specialized Laboratories and Equipment

The Institute for Quantum Computing (IQC) at the maintains several specialized laboratories equipped with advanced tools essential for quantum research. These facilities are housed primarily within the Mike & Ophelia Lazaridis Quantum-Nano Centre (QNC) and other dedicated spaces on campus, providing controlled environments for precise experimentation. Ultracold atom and trapped-ion laboratories, located in the QNC, are designed for quantum simulation experiments and feature dilution refrigerators capable of reaching millikelvin temperatures, along with sophisticated systems for manipulation and cooling. These labs incorporate stringent environmental controls, including a rating of VC-E (less than 3 micrometers floor deflection per second), temperature stability of ±0.1 °C, humidity maintained at 45% ±3%, and radio-frequency interference/ shielding below 1 milligauss peak-to-peak to minimize external disturbances. The Quantum-Nano Fabrication and Characterization Facility (QNFCF), also situated in the QNC, supports and photonic device fabrication through ISO 4, 5, and 6 certified bays equipped with systems for nanoscale patterning, cryogenic measurement setups for low-temperature characterization, (FIB) processing tools, and (TEM) for high-resolution imaging. Additional capabilities include a and device lab to integrate fabricated components. The Transformative Quantum Technologies (TQT) lab, based in the Quantum Exploration Space, enables prototyping of quantum devices in vibration-isolated environments to reduce mechanical noise, and is outfitted with specialized quantum technologies for device assembly and testing. This facility bridges foundational research and practical development by providing access to integrated tools for scalable quantum hardware.

Education and Outreach

Academic Programs

The Institute for Quantum Computing (IQC) at the provides interdisciplinary graduate programs in , enabling students to pursue advanced degrees while integrating expertise from multiple academic departments. These programs emphasize theoretical and experimental aspects of quantum technologies, fostering skills essential for research and innovation in the field. IQC offers MMath, , MASc, and degrees with a specialization in , administered jointly with faculties including , , Combinatorics and Optimization, , Electrical and Computer Engineering, Physics and Astronomy, and . Students complete core coursework and thesis research under IQC faculty supervision, with degree requirements tailored to the home department while incorporating quantum-specific milestones such as qualifying exams and seminars. Specialized courses within these programs cover key areas of , including quantum algorithms (e.g., QIC 823), (e.g., QIC 890 on applied quantum cryptography and QIC 891 on ), and experimental techniques (e.g., QIC 895 on quantum communication implementations). These courses provide hands-on training in topics like qubits, quantum dots, and , drawing on IQC's research infrastructure to bridge theory and practice. As of 2023–2024, over 200 graduate students are affiliated with IQC programs, supported by research assistantships tied to faculty-led projects in and related fields. Postdoctoral fellowships are also available, often funded through initiatives like CryptoWorks21, which provide supplemental training in quantum-safe and connect fellows to collaborative research efforts.

Events and Collaborations

The Institute for Quantum Computing (IQC) hosts the annual Quantum Innovators , a five-day event initiated in 2012 to gather promising postdoctoral fellows from around the world for intensive collaboration and knowledge exchange. The 2025 edition, held from October 27 to 31, featured sessions on , , and theory, alongside and , emphasizing applications in quantum technologies. This fosters cross-disciplinary discussions, with participants presenting and engaging in group problem-solving to advance quantum innovation. IQC co-organizes regular workshops on quantum-safe technologies, including the /IQC Quantum Safe Cryptography Conference, which addresses the transition to resilient systems against quantum threats. The 2025 conference, held on June 3–5 in , facilitated knowledge sharing among researchers, policymakers, and industry experts on and secure protocols. These events promote practical implementations and standardization efforts to mitigate risks from emerging capabilities. Interdisciplinary seminars at IQC, such as the Graduate Student Seminar Series and IQC Math and CS Seminar, connect members across diverse research areas, enhancing skills and networking for graduate students and postdocs. Open to all IQC affiliates, these sessions include technical talks on topics, with formats blending in-person and online participation to broaden accessibility. The IQC-PI Joint Student Seminar Series further extends this by alternating between IQC and the Perimeter Institute, encouraging collaborative presentations on and applications. Internally, IQC supports collaborations across its 27 research groups, spanning , , , and error correction, where faculty, students, and postdocs jointly advance projects. Groups like the Quantum Interactions Theory Group explicitly partner with experimental teams to integrate theoretical insights with device , promoting cross-departmental initiatives within the Faculties of , and Science. This structure enables over 350 researchers to tackle multifaceted quantum challenges through shared resources and interdisciplinary teams.

Impact and Developments

Recent Achievements

In 2025, researchers from the Institute for Quantum Computing (IQC) at the collaborated with the to develop a novel qudit-based quantum computer designed to simulate the dynamics of elementary particles. This unconventional system enables the study of quantum field theories by leveraging higher-dimensional quantum states (qudits) rather than traditional binary qubits, offering improved efficiency for modeling complex particle interactions such as those in lattice gauge theories. The collaboration demonstrated the platform's potential for advancing fundamental physics research, with experimental results showing accurate simulation of particle dynamics under quantum conditions. Advancements in trapped-ion quantum systems at IQC have focused on enhancing qubit fidelity and scalability. In 2024, IQC researchers achieved a breakthrough in non-destructive state measurement and reset of trapped-ion s, maintaining fidelity above 99% without perturbing adjacent qubits, which is crucial for error-corrected . This technique uses advanced optical control to isolate measurement processes, paving the way for larger-scale ion-trap arrays. Complementing these efforts, IQC has pioneered quantum light sensors for medical applications. Additionally, a quantum camera developed in early 2025 utilizes structured light patterns to image tumors at the cellular level, improving diagnostic accuracy in biomedical imaging. IQC has made significant contributions to Canada's national quantum strategies, including advocacy for increased funding that culminated in the 2025 federal budget allocating $334.3 million for development and talent training. In parallel, IQC researchers have published influential work on scalable quantum networks, such as a 2021 for photonic fault-tolerant systems capable of linking modules to exceed 100 logical qubits through distributed entanglement. These publications emphasize architectures and error mitigation to enable long-distance quantum communication, supporting national goals for secure quantum infrastructure.

Partnerships and Commercialization

The Institute for Quantum Computing (IQC) fosters extensive partnerships with industry, government, and investment entities to translate quantum research into practical applications. Key collaborations include Quantum Valley Investments (QVI), a $100 million fund established by and Doug Fregin to commercialize technologies emerging from Waterloo-based institutions like IQC. These alliances extend globally, encompassing over 35 industry partnerships that advance quantum hardware, software, and applications, while integrating private-sector expertise with academic innovation. A prominent initiative is CryptoWorks21, a NSERC-funded program co-founded by IQC faculty member Michele Mosca, which trains graduate students and postdocs in developing and commercializing quantum-safe cryptographic tools resistant to quantum attacks. Involving government agencies, private firms, and academic mentors, CryptoWorks21 bridges research with industry needs through workshops, courses, and projects focused on standards like those from the Standards Institute (ETSI), facilitating the adoption of in sectors such as finance and telecommunications. IQC's technology transfer efforts have spawned over 20 companies, driving commercialization of quantum technologies including (QKD) systems for secure communications. Notable examples include Aegis Quantum, which develops and implements QKD-based solutions for government and enterprise clients, and QEYnet, which is building a satellite-based global QKD network to enable ultra-secure data transmission. These spin-offs, supported by IQC's infrastructure and the Commercialization Office, have contributed to an ecosystem employing approximately 650 people in quantum businesses in the Waterloo region, with biennial growth of about 10% since 2021.

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