Thermal conductivity measurements of Summit             polycrystalline silicon.

Clemens, Rebecca; Kuppers, Jaron; Phinney, Leslie M.

doi:10.2172/897917

Cited by 3 publications

(1 citation statement)

References 6 publications

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“…The temperature rise on the surface was calculated using the steady state heat equation [27]:T(x,y)=true∬ A 8Pπd2e−(2 × 2d)2(x2+y2)12πκ(x2+y2)dx dy. where A is the absorbance of the laser, P the laser power and d the diameter of the laser spot. The material parameters of the polysilicon, like the thermal conductivity κ, but also A , are temperature-dependent [28], so the temperature increase was calculated for all the different temperatures set by the Pt-heater during calibration. In Figure 3, the Gaussian weighted average of the temperature rise can be seen as a function of each set temperature.…”

Section: Resultsmentioning

confidence: 99%

In-Situ Temperature Measurement on CMOS Integrated Micro-Hotplates for Gas Sensing Devices

Deluca

Wimmer-Teubenbacher

Mitterhuber

et al. 2019

Sensors

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Metal oxide gas sensors generally need to be operated at elevated temperatures, up to and above 400 °C. Following the need for miniaturization of gas sensors and implementation into smart devices such as smartphones or wireless sensor nodes, recently complementary metal-oxide-semiconductor (CMOS) process-based micro electromechanical system (MEMS) platforms (micro-hotplates, µhps) have been developed to provide Joule heating of metal oxide sensing structures on the microscale. Heating precision and possible spatial temperature distributions over the µhp are key issues potentially affecting the performance of the overall gas sensor device. In this work, we use Raman spectroscopy to directly (in-situ and in-operando) measure the temperature of CMOS-based µhps during the application of electric current for Joule heating. By monitoring the position of the Raman mode of silicon and applying the theoretical framework of anharmonic phonon softening, we demonstrate that state-of-the-art µhps are able to reach the set temperature with an error below 10%, albeit with significant spatial temperature variations on the hotplate. This work demonstrates the potential of Raman spectroscopy for in-situ and in-operando temperature measurements on Si-based devices, an aspect of high relevance for micro- and nano-electronic device producers, opening new possibilities in process and device control.

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Section: Resultsmentioning

confidence: 99%

In-Situ Temperature Measurement on CMOS Integrated Micro-Hotplates for Gas Sensing Devices

Deluca

Wimmer-Teubenbacher

Mitterhuber

et al. 2019

Sensors

View full text Add to dashboard Cite

show abstract

Modified data analysis for thermal conductivity measurements of polycrystalline silicon microbridges using a steady state Joule heating technique

Sayer

Piekos

Phinney

2012

Review of Scientific Instruments

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Accurate knowledge of thermophysical properties is needed to predict and optimize the thermal performance of microsystems. Thermal conductivity is experimentally determined by measuring quantities such as voltage or temperature and then inferring a thermal conductivity from a thermal model. Thermal models used for data analysis contain inherent assumptions, and the resultant thermal conductivity value is sensitive to how well the actual experimental conditions match the model assumptions. In this paper, a modified data analysis procedure for the steady state Joule heating technique is presented that accounts for bond pad effects including thermal resistance, electrical resistance, and Joule heating. This new data analysis method is used to determine the thermal conductivity of polycrystalline silicon (polysilicon) microbridges fabricated using the Sandia National Laboratories SUMMiT V™ micromachining process over the temperature range of 77-350 K, with the value at 300 K being 71.7 ± 1.5 W/(m K). It is shown that making measurements on beams of multiple lengths is useful, if not essential, for inferring the correct thermal conductivity from steady state Joule heating measurements.

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MEMS solar energy harvesting.

Nielson¹,

Resnick²,

Epp³

et al. 2007

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We have performed a preliminary investigation of a new approach for generating electrical power with solar energy that does not rely on the photovoltaic effect. This approach takes advantage of a unique interaction between a mechanically resonant device and optical illumination. The optical illumination is required to be a plane wave but does not require optical coherence which other reported optically excited mechanical resonant devices have required. The preliminary investigation described in this report included both experimental demonstration of key portions of the energy conversion process and FEA simulations to better understand the dependencies of this approach. This report also describes possible future areas of research. 4

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Thermal conductivity measurements of Summit polycrystalline silicon.

Cited by 3 publications

References 6 publications

In-Situ Temperature Measurement on CMOS Integrated Micro-Hotplates for Gas Sensing Devices

In-Situ Temperature Measurement on CMOS Integrated Micro-Hotplates for Gas Sensing Devices

Modified data analysis for thermal conductivity measurements of polycrystalline silicon microbridges using a steady state Joule heating technique

MEMS solar energy harvesting.

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