Article Highlight

Quantum materials cloak thermal radiation

A unique coating camouflages the temperature of an underlying material

DOE/US Department of Energy

The Science

Scientists demonstrated that ultrathin films of samarium nickel oxide can mask the thermal radiation emitted by hot materials. Samarium nickel oxide is a quantum material. These are materials that have strange and incredible properties due to quantum mechanics. The cloaking mechanism is due to the material undergoing a unique, gradual transition from insulator to heat-conducting metal. This transition occurs over a temperature range from 100 to 140 degrees centigrade.

The Impact

This study shows that quantum materials can manage thermal radiation. This ability could advance applications such as infrared camouflage, privacy shielding, and heat transfer control. The 100-140 degree centigrade heat range is important because it can be seen with infrared cameras.


Conventional wisdom states that the hotter an object is, the brighter it glows. This is the case for thermal light at any wavelength and enables applications such as infrared imaging and noncontact thermometry. However, researchers at the Department of Energy (DOE) Center for Functional Nanomaterials at Brookhaven National Laboratory demonstrated a coating that emits the same amount of thermal radiation regardless of temperature, within a temperature range of about 30 degrees centigrade. This is accomplished using samarium nickel oxide—a quantum material that changes strongly but gradually as a function of temperature. This is the first time researchers have demonstrated temperature-independent thermal radiation. The results have substantial implications for infrared camouflage, privacy shielding, and radiative heat transfer.


This research was supported by Office of Naval and the National Science Foundation, the Air Force Office of Scientific Research, and a Critical Skills Master’s Fellowship from Sandia National Laboratories. Some measurements were performed at the Soft Materials Characterization Laboratory at the University of Wisconsin–Madison. This research used resources of the Center for Functional Nanomaterials and National Synchrotron Light Source II, both of which are DOE Office of Science user facilities at Brookhaven National Laboratory.

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