The thermal performance of microelectromechanical systems devices is governed by the structure and composition of the constituent materials as well as the geometrical design. With the continued reduction in the characteristic sizes of these devices, experimental determination of the thermal properties becomes more difficult. In this study, the thermal conductivity of polycrystalline silicon (polysilicon) microbridges are measured with the transient 3ω technique and compared with measurements on the same structures using a steady state Joule heating technique. The microbridges with lengths from 200μm to 500μm were designed and fabricated using the Sandia National Laboratories SUMMiT V™ surface micromachining process. The advantages and disadvantages of the two experimental methods are examined for suspended microbridge geometries. The differences between the two measurements, which arise from the geometry of the test structures and electrical contacts, are explained by bond pad heating and thermal resistance effects.

Issue Section:
Micro/Nanoscale Heat Transfer—Part Ii
Keywords:
micromechanical devices, silicon, thermal conductivity, thermal conductivity, 3ω technique, polycrystalline silicon, suspended microbridge, thermal boundary resistance
Topics:
Polysilicon, Thermal conductivity, Temperature, Steady state, Bridges (Structures)
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