Thermal and Electrical Properties of a Suspended Nanoscale Thin Film

Zhang, X.; Xie, Huaqing; Fujii, Minoru; Ago, Hiroki; Takahashi, Kazuhiko; Ikuta, Tatsuya; Abe, Haruka; Shimizu, Tetsuo

doi:10.1007/s10765-006-0135-1

Cited by 29 publications

(17 citation statements)

References 18 publications

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“…It has been shown that many material properties such as electrical, optical, and thermodynamic are affected if a material's dimensions are reduced to the nanoscale [25]- [29]. Also, experimental evidence has recently shown that the electrical resistance of thin-film conductors in general or thin-film platinum RTDs in particular do not behave exactly as bulk materials [30]- [33]. Since it is well known that the mean free path of electrons in nanosized materials is smaller compared to electrons in bulk materials [34]- [36], care must be taken if the expression in (6) is used to determine the electrical resistivity of conductors when they are not in bulk form.…”

Section: Discussionmentioning

confidence: 99%

Evaluating the Resistivity-Temperature Relationship for RTDs and Other Conductors

Lacy

2011

IEEE Sensors J.

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It has long been established from experimental evidence that resistance temperature detectors (RTDs) and conductors in bulk form have an electrical resistivity that is a linear function of temperature. Although this experimental data has existed for some time, there has not been a straightforward model to explain the mechanisms leading to this relationship. In order to better understand the nature of this relationship, a microscopic model is needed so that analysis of the electrons in the material can be performed. Therefore, a theoretical framework using solid-state physics and quantum mechanics principles is presented and developed to obtain an equation for bulk conductors that relates resistivity to temperature. It is then shown that this newly developed equation produces a linear relationship for conductors and provides a very good match with experimental data obtained from platinum and nickel RTDs. Therefore, this newly developed theoretical model provides great insight into the mechanisms of experimental findings.Index Terms-Callendar-van Dusen, conductivity, mean free path, resistance temperature detector (RTD), temperature sensor.

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Section: Discussionmentioning

confidence: 99%

Evaluating the Resistivity-Temperature Relationship for RTDs and Other Conductors

Lacy

2011

IEEE Sensors J.

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“…In Figure 4.7, as expected, the electrical resistance increases with increasing the heating current from 11 to 18 mA. At a current of 18 mA, we estimate the maximum temperature to be [390 K], based on the temperature coefficient of thin film gold (0.0017 K −1 (Zhang et al, 2007)). Above 18 mA we suspect that electromigration occurs.…”

Section: Electrical and Thermal Propertiessupporting

confidence: 70%

3D Nanofabrication of fluidic components by corner lithography

Burouni¹

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“…16. The CNTs were made by an arc-discharge evaporation method and an individual multiwall CNT with a high quality and an available length was selected and fixed to the nanotip of a metallic needle by using local focused electron beam irradiation with the help of a manipulation SEM.…”

Section: A Sample Fabricationmentioning

confidence: 99%

Optical absorptance measurement of an individual multiwall carbon nanotube using a T type thermal probe method

Liu

Wang

et al. 2013

Review of Scientific Instruments

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Optical absorptance is an important property of carbon nanotubes for practical applications but has rarely been accurately measured. We developed a T type thermal probe method to measure the optical absorptance of an individual multiwall carbon nanotube. In this method, one end of the carbon nanotube (CNT) is attached to the center of a platinum nanofilm in a T shape and the Pt nanofilm acts as a thermometer. A laser beam irradiates at the CNT and the absorbed laser power can be determined by measuring the average temperature rise of the Pt nanofilm based on the temperature dependence of the electric resistance. Experimental results showed that a 100-nm-diameter multiwall CNT could absorb 13.2% of the 514-nm-wavelength laser power with the laser spot diameter being 1 μm. This method is useful for determining the optical absorptance of CNTs and other one-dimensional nanostructures such as Si/Ge nanowires for various optical wavelengths in their photovoltaic, photoelectrolysis and other optical applications.

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Thermal and Electrical Properties of a Suspended Nanoscale Thin Film

Cited by 29 publications

References 18 publications

Evaluating the Resistivity-Temperature Relationship for RTDs and Other Conductors

Evaluating the Resistivity-Temperature Relationship for RTDs and Other Conductors

3D Nanofabrication of fluidic components by corner lithography

Optical absorptance measurement of an individual multiwall carbon nanotube using a T type thermal probe method

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