NEAR-FIELD THERMAL RADIATION BETWEEN TWO PLATES WITH SUB-10 NM VACUUM SEPARATION.

Radiation greatly exceeding blackbody between two objects separated by microscale distances has attracted great interest. However, challenges in reaching small separation between two plates have so far prevented studies below a separation distance of about 25 nm. Here, we report a study of radiation enhancement in the near-field regime of less than 10 nm between two parallel plates. We make use of bulk, rigid plates to approach small separation distances without the adverse snap-in effect, develop embedded temperature sensors to allow near-zero separation, and employ advanced sensing method to level the plates and approach and maintain small separations. Our findings agree with theoretical predictions between parallel surfaces with separations down to 7 nm where an 18,000 times enhancement in radiation between two quartz plates is observed. Our method can also be used to explore heat transfer between other materials, and can possibly be extended to smaller separation gaps.