Application of the thermal flash technique for low thermal diffusivity micro/nanofibers

Demko, Michael T.; Dai, Zhaoxin; Yan, Han; King, William P.; Cakmak, Mukerrem; Abramson, Alexis R.

doi:10.1063/1.3086310

Cited by 19 publications

(14 citation statements)

References 19 publications

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“…In comparison, it is feasible to determine the heating in the cantilever rather conveniently and accurately if the heating is provided by electrical heating of a doped Si or Pt-C resistor fabricated at the end of a cantilever. 49,50 This type of resistance thermometer can achieve 3 mK temperature sensitivity with the use of lock-in detection combined with a Wheatstone bridge. The resistance of the thermometer can also be calibrated readily as a function of the cantilever temperature, and the method is free of the complication caused by thermal drifting of the laser beam as well as cantilever deflection caused by mechanical strain applied by the nanofiber.…”

Section: Direct Thermal Conductance Measurement With Bimateral Cantilmentioning

confidence: 99%

“…Resistance thermometer cantilever sensors have been explored for thermal diffusivity measurements of polymer fibers by Demko et al 49 The thermal sensor is a Si cantilever with two heavily doped beams connected by a lightly doped Si region that acts as the resistance thermometer (see Fig. 11).…”

Section: Thermal Diffusivity Measurements With Doped Si Cantilever Rementioning

confidence: 99%

“…In addition, because the lightly doped resistance thermometer sensor has a finite size, l RT , the thermal time constant of the sensor needs to be considerably smaller than that of the fiber, that is, l 2 RT /α s 2 f /α f , in order to establish sufficient transient response of the sensor. In the work of Demko et al, 49 the samples were glass fibers and polyimide fibers with considerably lower thermal diffusivity than the Si sensor. For extending this method to a high-thermal diffusivity carbon nanotube of a finite length, the size of the resistance thermometer may need to be reduced to be considerably smaller than the length of the nanotube sample.…”

Section: Thermal Diffusivity Measurements With Doped Si Cantilever Rementioning

confidence: 99%

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Thermal Transport Measurement Techniques for Nanowires and Nanotubes

Weathers

Shi

2013

Annual Rev Heat Transfer

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Recent advances in the synthesis of inorganic and organic nanowires and nanotubes have provided both components for various functional devices and platforms for the study of low-dimensional transport phenomena. However, tremendous challenges have remained not only for the integration of these building blocks into functional devices, but also in the characterization of the fundamental transport properties in these nanoscale model systems. In particular, thermal and thermoelectric transport measurements can be considerably more complicated than electron transport measurements, especially for individual nanostructures. During the past decade, a number of experimental methods for measuring the thermal and thermoelectric properties of individual nanowires and nanotubes have been devised to address these challenges, some of which are reviewed and analyzed in this chapter. Although the Seebeck coefficient and electrical conductivity can also be obtained from some of the measurement methods, this chapter is focused on measurement techniques of the thermal conductivity and thermal diffusivity of nanowires and nanotubes. It is suggested that the limitations in the current experimental capability will provide abundant opportunities for innovative approaches to probing fundamental thermal and thermoelectric transport phenomena in individual nanostructures.

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Section: Direct Thermal Conductance Measurement With Bimateral Cantilmentioning

confidence: 99%

Section: Thermal Diffusivity Measurements With Doped Si Cantilever Rementioning

confidence: 99%

Section: Thermal Diffusivity Measurements With Doped Si Cantilever Rementioning

confidence: 99%

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Thermal Transport Measurement Techniques for Nanowires and Nanotubes

Weathers

Shi

2013

Annual Rev Heat Transfer

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“…This article focuses on the mathematical formalism behind a technique developed on the thermal flash principle 12,13 to facilitate direct characterization of the true conductivity of the material without being influenced by the presence of interfacial or contact resistances. While the thermal flash method has been presented previously by the authors as a technique employed to measure thermal diffusivity/conductivity at the nanoscale, 13 this is the first attempt at substantiation that no a) Author to whom correspondence should be addressed.…”

Section: Introductionmentioning

confidence: 99%

The thermal flash technique: The inconsequential effect of contact resistance and the characterization of carbon nanotube clusters

Mahanta

Abramson

2012

Review of Scientific Instruments

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This article presents a comprehensive mathematical treatment of the theory behind the thermal flash technique used to measure the thermal diffusivity of nanostructures. Analytical expressions predicting the temperature and its rate of change for various combinations of sample length and diffusivity confirmed that the presence of contact resistance between the heat sink/source or within a cluster of materials does not influence the measurement. Measurements on multi-walled carbon nanotube clusters provide further experimental evidence supporting the claim that contact resistance is inconsequential to this technique and yield a thermal conductivity of 2665 W/m K, which corresponds to an isolated nanotube and not the overall cluster.

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“…The reliability and accuracy of this method were, to a large extent, limited by the thermal contact resistance between the sample and the hot wire and the uncertainty related to the geometry. Inspired by the laser flash method, Demko et al 5 proposed a thermal flash method that utilized a micromanipulator to supply heat and a microfabricated sensor to determine the temperature response. This approach, however, was only suitable for fibers with low thermal diffusivity.…”

mentioning

confidence: 99%

Note: Thermal conductivity measurement of individual poly(ether ketone)/carbon nanotube fibers using a steady-state dc thermal bridge method

Moon

Weaver

Feng

et al. 2012

Review of Scientific Instruments

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Customized engineered fibers are currently being used extensively in the aerospace and automobile industries due to the ability to “design in” specific engineering characteristics. Understanding the thermal conductivity of these new fibers is critical for thermal management and design optimization. In the current investigation, a steady-state dc thermal bridge method (DCTBM) is developed to measure the thermal conductivity of individual poly(ether ketone) (PEK)/carbon nanotube (CNT) fibers. For non-conductive fibers, a thin platinum layer was deposited on the test articles to serve as the heater and temperature sensor. The effect of the platinum layer on the thermal conductivity is presented and discussed. DCTBM is first validated using gold and platinum wires (25 μm in diameter) over a temperature ranging from room temperature to 400 K with ±11% uncertainty, and then applied to PEK/CNT fibers with diverse CNT loadings. At a 28 wt. % CNT loading, the thermal conductivity of fibers at 390 K is over 27 Wm−1K−1, which is comparable to some engineering alloys.

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Application of the thermal flash technique for low thermal diffusivity micro/nanofibers

Cited by 19 publications

References 19 publications

Thermal Transport Measurement Techniques for Nanowires and Nanotubes

Thermal Transport Measurement Techniques for Nanowires and Nanotubes

The thermal flash technique: The inconsequential effect of contact resistance and the characterization of carbon nanotube clusters

Note: Thermal conductivity measurement of individual poly(ether ketone)/carbon nanotube fibers using a steady-state dc thermal bridge method

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