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The most important applications of controlling heat transport are in fields such as thermoelectric power conversion and cooling, and bolometric radiation detection.

The holey structures consisted of thin insulating silicon nitride plates containing a periodic array of holes in two directions. In principle, any other material could be used, as well. In particular, the group demonstrated that there is an optimal periodic structure, which minimizes the thermal conduction to a record low level, with a period of about 10 micrometers.

In addition, it was realized that if the hole side surfaces could be fabricated with atomic precision, heat conduction could be reduced even further with larger period structures.

"In the future, we will use these results  to improve sensitive infrared radiation detectors for future space research, in collaboration with NASA", says professor Ilari Maasilta. 

The study was funded by the Academy of Finland. 

Article: ”Minimizing Coherent Thermal Conductance by Controlling the Periodicity of Two-Dimensional Phononic Crystals” (Yaolan Tian, Tuomas A. Puurtinen, Zhuoran Geng, and Ilari J. Maasilta), Phys. Rev. Applied 12, 014008 (2019)

Link to publication:

Link to research of thermal nanophysics at Ģ��ֱ��: /science/en/physics/research/materials-physics/thermal-nanophysics

More information:
Professor Ilari Maasilta, ilari.j.maasilta@jyu.fi , tel. +358408054098
Communications officer Tanja Heikkinen, tanja.s.heikkinen@jyu.fi, tel. +358 50 581 8351
/science/en
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