
"By putting students directly in contact with active research challenges and real commercialization questions, the practicum is designed to help close the gap between academic discovery and industry-ready quantum tools" - J Flatté
June 30, 2026
QuantCAD is proud to announce its role as a key partner in the U.S. National Science Foundation's (NSF) National Quantum Virtual Laboratory (NQVL) project on Distributed-Entanglement Quantum Sensing of Chemical Properties (DQS-CP). Led by The Ohio State University this $4,000,000 Phase II Design Award brings together a cross-disciplinary team to build a testbed for advancing next-generation quantum sensing technology toward real-world use.
During the two-year award, QuantCAD will develop a two-week practicum designed to provide undergraduate and early graduate students with hands-on experience in the interdisciplinary skills needed to achieve quantum advantage in sensing. Across several student cohorts, participants will work to address current technical roadblocks identified in the NQVL Quantum Sensing Roadmap. Beyond the technical challenges, each cohort will also examine potential real-world applications for quantum sensing and learn how to develop commercialization transition plans.
"By putting students directly in contact with active research challenges and real commercialization questions, the practicum is designed to help close the gap between academic discovery and industry-ready quantum tools," said Jennifer Flatté, Chief Executive Officer of QuantCAD and project lead for QuantCAD.
The practicum reflects QuantCAD's ongoing commitment to translating quantum research into practical, deployable technology while helping prepare the next generation of scientists and engineers. By combining technical problem-solving with commercialization planning, QuantCAD's program is intended to give students experience that extends beyond the laboratory and exposes them to the challenges of bringing emerging quantum technologies into real-world use.
The broader DQS-CP project also will build the workforce needed to support a growing U.S. quantum ecosystem. The testbed will coordinate collaboration between the quantum creator and end-user communities to develop a roadmap to quantum advantage, aligning research activities with critical needs in science and industry. Students participating in the DQS-CP program will be mentored within a highly interdisciplinary and convergent environment, while the testbed provides a platform for hands-on workforce training for researchers and end users from both academia and industry.
"We are very happy to see this substantial NSF investment into researcher training for careers in the emerging U.S. quantum industry sector." said Dr. Michael Flatté, Chief Science Officer of QuantCAD. "This is especially vital for U.S. quantum startups like QuantCAD but also critical for other U.S. quantum technology companies."
Through its partnership with Ohio State and the National Quantum Virtual Laboratory, QuantCAD is helping build the technical foundation, workforce, and commercialization pathways needed to accelerate quantum sensing from promising research to practical technology. By combining education, interdisciplinary collaboration, and application-driven research, the DQS-CP initiative aims to strengthen the nation's quantum innovation ecosystem and prepare the next generation of leaders in the field.

The sensor limits the effects of diffusion noise on the optical signals using spin centers embedded within the walls of a container
July 16, 2024
QuantCAD LLC, a physics start-up operating in Iowa City, IA and Chicago, IL, was selected by NASA to advance quantum sensing with a Small Business Innovation Research (SBIR) Phase II contract. NASA plans to use the quantum sensor developed by QuantCAD to investigate the origins of water on exoplanets.
Over the next two years, QuantCAD will refine a prototype quantum sensor for measuring the isotopic composition of water - specifically the ratio of deuterium to hydrogen. The proposed device features high sensitivity and significantly reduces the weight typically associated with conventional sensors that use technology similar to magnetic resonance imaging (MRI) tools. In addition, the QuantCAD device can operate for extended periods in challenging environments as it does not require consumables. Ivan Viti, Quantum Systems Engineer at QuantCAD and PI for the Phase I noted “Our technology marks a turning point in the ability to trace water sources across the solar system, unlocking new possibilities for pinpointing water origins, crucial for future missions.”
The sensor limits the effects of diffusion noise on the optical signals using spin centers embedded within the walls of a container. QuantCAD has calculated a sensitivity improvement of up to 100,000x compared to systems using MRI-like technology classical NMR systems. “Our aim is to decipher the origins of solar system water, a pivotal step that promises to unlock profound insights into the early evolution and composition of the moon and the inner Solar System” explains Fabrizio Sgrignuoli, QuantCAD Physicist and PI for Phase II. This low-cost, robust to rough environments, lightweight, and small footprint technology represents a significant forward step toward sustainable space exploration programs.
This is the second Phase II contract awarded to QuantCAD by NASA in the area of quantum sensing. NASA has also selected QuantCAD for a third Phase I award which will expand their sensing capabilities in extreme environments. The increasing support validates QuantCAD’s approach and expands their ability to innovate within the aerospace sector. QuantCAD founder and CEO, Jennifer Flatté observed, “In an era when women- and minority- owned businesses still struggle for equal access, these contracts allow our company to continue its mission to advance low-noise quantum sensing while also spearheading diversity and inclusion in the workspace.”

QuantCAD’’s magnetometers are intended to probe magnetic fields such as those near Jupiter’smoon Europa; this NASA image shows the magnetic field distortions near Europa caused by Europa Clipper’s own stray fields
July 5, 2023
Federal agencies awarded $1.5 million in contracts this spring to QuantCAD, a Chicago Quantum Exchange corporate partner and a graduate of the quantum accelerator Duality, for the design and manufacture of ultra-sensitive quantum sensors that could be sent into space to detect water, used to measure magnetic fields at extremely high temperatures, and incorporated into cellular-level medical imaging.
The three contracts, two from NASA and one from the Defense Advanced Research Projects Agency (DARPA), represent the enormous potential of quantum sensing to advance a variety of scientific fields with cutting-edge real-world applications. Using quantum mechanics, these microscopic sensors need only the barest signal—even a single ion—to make a measurement, making them much more precise in many cases than classical sensors.
The potential applications of the tiny-but-robust sensors QuantCAD is developing span a large range of fields: aerospace, as magnetic navigation for airborne devices that can’t use GPS; health, as a method of measuring the heart’s magnetic fields and detecting molecular biomarkers; geological prospecting and the study of underground/underwater anomalies; planetary probing and solar weather monitoring; and the development of new materials. Their tiny size also expands their applications to technology like nanosatellites—small satellites that can be sent further and more easily into space due to their low weight.
“These three projects give us the opportunity to take our groundbreaking theory and apply it to solve real-world problems,” said Adonai Cruz, principal scientist at QuantCAD, an Iowa City and Chicago based company that develops simulation software for modelling noise and current in quantum devices such as high-resolution quantum sensors. “Contracting with both of these government agencies provides an incredible opportunity for QuantCAD to advance the technology of quantum sensing.”ntract enables us to broaden our research team and further develop our partnerships within the quantum community.”
The contracts also represent an opportunity to help train early-career professionals. As part of its commitment to developing a highly skilled and significantly diverse quantum workforce, QuantCAD plans to provide an opening associated with each of these contracts for an undergraduate or recently graduated intern to get hands-on experience working in quantum technology and experiencing the life of a startup company first-hand. These internships will provide opportunities to develop a wide range of specific skills including coding, creating and testing step-by-step manuals for core products, the development of market segment sales databases along with a marketing campaign for quantum sensors, and the creation of web-based introductions to quantum sensing for non-scientists.
In 2021, QuantCAD was a member of Cohort 1 of Duality, the nation’s first accelerator program exclusively focused on supporting quantum startups. This year, the company received both a Phase I contract and a Phase II contract from NASA. Phase I projects are judged by their technical merit and commercial potential; companies that receive a Phase I contract may submit a subsequent proposal for Phase II funding, which is used to develop a prototype.
The Phase II funding builds on a project that received Phase I funding in 2022: highly sensitive atomic magnetometers, which measure magnetic fields. Unlike other magnetometers of its size, which usually need special optical equipment, these magnetometers only need electronics. They could be used to search for life on other planets, study the minerals of asteroids, or monitor solar flares. To make these sensors, QuantCAD will be working with GE Research, Pennsylvania State University, and the Jet Propulsion Laboratory.
The new Phase I project is a quantum sensor that uses the same principles as magnetic resonance imaging (MRI) machines to analyze water on other planets. Magnetic resonance technology at such a small scale is invaluable for the biological sciences, with such applications as imaging molecules or nanoparticles, or detecting biomarkers within a single cell.
The third project answers a call from DARPA for the development of magnetometers that can withstand extremely high temperatures. QuantCAD’s proposed magnetometer does not need optical equipment, and also exploits magnetic resonance principles in the same vein as the NASA Phase I product—but this magnetometer would remain operational for over 40 hours at temperatures above 750 degrees Fahrenheit (400 degrees Celsius).
“Our projects for both NASA and DARPA will further QuantCAD's mission to build high sensitivity, low noise quantum sensors,” said Jennifer Flatté, CEO of QuantCAD. “I am just as delighted to note that they will also provide additional opportunities for the development of a highly skilled and significantly diverse workforce within the quantum sector.”

NASA has awarded QuantCAD a $150,000 Small Business Innovation Research (SBIR) Phase I grant to develop and test quantum magnetic sensors for use in various applications. Under the proposal, QuantCAD will design high-sensitivity isotopically-purified all-electrical chip-scale atomic magnetometers. These will have orders of magnitude improved sensitivity if the semiconductor hosts are isotopically purified and related device parameters optimized.
“Quantum sensing is a revolutionary set of technologies that promise inexpensive and efficient detectors. This all-electrical magnetometer is particularly exciting due to its emphasis on quantum sensing without complex optics or microwave circuitry,” said Michael Flatté, chief scientist at QuantCAD. These small-scale magnetometers avoid challenges related to gas diffusion through glass cells, radiation damage associated with fiberoptics, and, unlike fluxgate magnetometers, do not need to self-calibrate.
The devices have several applications in aerospace, health, and noninvasive materials monitoring. Examples include GPS-denied navigation, magnetocardiography, underground/underwater anomaly detection, planetary probing and solar weather monitoring, and high-resolution crack detection.
"As a company, we are excited by this opportunity to further our mission of enabling the rapid growth of quantum devices,” said QuantCAD CEO Jennifer Flatté. “This contract enables us to broaden our research team and further develop our partnerships within the quantum community.”
“NASA is working on ambitious, groundbreaking missions that require innovative solutions from a variety of sources – especially our small businesses,” said NASA Deputy Administrator Pam Melroy. “Small businesses have the creative edge and expertise needed to help our agency solve our common and complex challenges, and they are crucial to maintaining NASA’s leadership in space."

Duality, the nation’s first accelerator exclusively for quantum companies, has accepted QuantCAD as part of their first cohort. Duality is the first-of-its-kind accelerator aimed at supporting next-generation startups focused on quantum science and technology. The 12-month program provides world-class business and entrepreneurship training from the University of Chicago Booth School of Business, Polsky Center, and the opportunity to engage the networks, facilities, and programming from the Chicago Quantum Exchange, the University of Illinois Urbana-Champaign Argonne National Laboratory, and P33.