Scientists have hacked the rules of light–matter interaction to spot disease earlier than ever before.
A Johns Hopkins team has unveiled a novel way to observe molecular vibrations, using light to create hybrid states with molecules that expose even the faintest signals.
The breakthrough, led by mechanical engineering professor Ishan Barman, could transform early disease detection, ranging from infections and metabolic disorders to cancer.
Molecular vibrations are tiny, unique movements of atoms within a molecule, which offer chemical “fingerprints” with unprecedented clarity.
Rewiring light for health
In healthcare, the method could enable earlier, more accurate detection of disease biomarkers in blood, saliva, or urine.
Beyond medicine, it may also transform pharmaceutical manufacturing by allowing real-time monitoring of complex chemical reactions, ensuring consistency and safety. Environmental scientists could use it to detect pollutants or hazardous compounds at trace levels with unprecedented reliability.
Techniques like infrared and Raman spectroscopy are often used to detect these vibrations, but their signals are faint, easily lost in background noise, and difficult to isolate in complex environments such as blood or tissue.
“We were trying to overcome a long-standing challenge in molecular sensing: How do you make optical detection of molecules more sensitive, more robust, and more adaptable to real-world conditions?” said Barman.
“Rather than trying to incrementally improve conventional methods, we asked a more radical question: What if we could re-engineer the very way light interacts with matter to create a fundamentally new kind of sensing?”
Using highly reflective gold mirrors to form an optical cavity, the team trapped the light, bouncing it back and forth to enhance its interaction with the enclosed molecules. As a result, the confined light field and molecular vibrations formed entirely new quantum states called “vibro-polaritons.”
Quantum sensing goes real
The team achieved this under normal, real-world conditions without relying on high-vacuum, cryogenic, or other extreme setups usually needed to preserve fragile quantum states.
Lead author Peng Zheng, an associate research scientist in mechanical engineering at Johns Hopkins, said the work turns “quantum vibro-polaritonic sensing” from a concept into a working platform, paving the way for a new class of quantum-enabled optical sensors.
“Rather than passively detecting molecules, we can now engineer the quantum environment around them to selectively enhance their optical fingerprints by utilizing the quantum vibro-polaritonic states,” said Zheng.
By applying quantum principles in a new way, without relying on bulky traditional infrastructure, the study marks a major step forward for ambient-condition quantum technologies. Barman envisions the approach leading to compact, chip-scale devices that could power portable diagnostic tools and AI-driven medical testing.
“The future of quantum sensing isn’t stuck in the lab—it’s poised to make a real-world impact across medicine, biomanufacturing, and beyond,” Barman said.
The work was supported by the National Institute of General Medical Sciences, with Steve Semancik, a physicist at the National Institute of Standards and Technology (NIST), serving as co-author.