Temperature measurements of heated microcantilevers using scanning thermoreflectance microscopy

Kim, Joohyun; Han, Sunwoo; Walsh, Timothy M.; Park, Keunhan; Lee, Bong Jae; King, William P.; Lee, Jungchul

doi:10.1063/1.4797621

Cited by 6 publications

(3 citation statements)

References 35 publications

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“…Figure 1 depicts the schematic TR experimental setup used in this study. [16][17][18] A probe laser beam with a wavelength of 532 nm (Coherent OBIS 1261777), which is highly sensitive to the temperature change in Au film, is modulated by a function generator and focused on a metal electrode of the LED sample through a microscope objective lens (100×). The diameter of the laser spot on the electrode of the LED surface is ∼3.0 μm.…”

Section: Methodsmentioning

confidence: 99%

Measuring the surface temperature of light-emitting diodes by thermoreflectance

Zheng¹,

Shin²,

Shim³

2021

Jpn. J. Appl. Phys.

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As the latest applications of LEDs require more harsh operating conditions, understanding the device thermal properties becomes more essential for further improving the device efficiencies. In applications where heat dissipation can be a critical issue, thermoreflectance (TR) can be utilized as a useful noncontact measurement technique for analyzing the thermal properties. In this paper, we investigate the TR method of measuring the surface temperature, using a lateral-type blue LED chip under high-power operation. The TR we employ measures the change in reflectivity from the Au metal electrode. By comparing with surface/junction temperatures measured by other methods based on the thermocouple and the forward voltage, we find that the TR method can provide accurate and reliable results of measuring the surface temperature of modern LEDs. A useful insight can also be obtained from the temperature distribution on the LED chip surface.

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Section: Methodsmentioning

confidence: 99%

Measuring the surface temperature of light-emitting diodes by thermoreflectance

Zheng¹,

Shin²,

Shim³

2021

Jpn. J. Appl. Phys.

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“…However, understanding the full spectrum 3ac signal of the doped-Si heated cantilever still remains challenging, mainly due to the inherent complexities of the cantilever, such as the presence of two doped regions, a nonlinear temperature dependence of the cantilever resistance, and the complicated geometry. While previous studies have attempted to predict the ac behaviors of the microcantilever with a simple 1D model [38,39,[49][50][51][52][53], they observed serious deviations of the 1D model from experimental data at high frequencies [51,52]. FEA was applied for the transient modeling of the cantilever during pulse and periodic heating operations [54].…”

Section: Introductionmentioning

confidence: 99%

Electrothermal Characterization of Doped-Si Heated Microcantilevers Under Periodic Heating Operation

Hamian

Gauffreau

Walsh

et al. 2016

Journal of Heat Transfer

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This paper reports the frequency-dependent electrothermal behaviors of a freestanding doped-silicon heated microcantilever probe operating under periodic (ac) Joule heating. We conducted a frequency-domain finite-element analysis (FEA) and compared the steady periodic solution with 3ω experiment results. The computed thermal transfer function of the cantilever accurately predicts the ac electrothermal behaviors over a full spectrum of operational frequencies, which could not be accomplished with the 1D approximation. In addition, the thermal transfer functions of the cantilever in vacuum and in air were compared, through which the frequency-dependent heat transfer coefficient of the air was quantified. With the developed FEA model, design parameters of the cantilever (i.e., the size and the constriction width of the cantilever heater) and their effects on the ac electrothermal behaviors were carefully investigated. Although this work focused on doped-Si heated microcantilever probes, the developed FEA model can be applied for the ac electrothermal analysis of general microelectromechanical systems.

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“…Thermoreflectance microscopy (TRM) is a contactless optical imaging technique that provides a twodimensional (2D) thermal image of microelectronic devices with high spatial and high thermal resolution [1][2][3][4][5]. TRM measures temperature-dependent changes in reflection using the thermo-optic response of a thermally modulated sample.…”

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confidence: 99%

High-speed thermoreflectance microscopy using charge-coupled device-based Fourier-domain filtering

et al. 2013

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We present a Fourier-domain filtering method for charge-coupled device (CCD)-based thermoreflectance microscopy to improve the thermal imaging speed while maintaining high thermal sensitivity. The time-varying reflected light distribution from the surface of bias-modulated microresistor was recorded by a CCD camera in free-run mode and converted to the frequency domain using the fast Fourier transform (FFT) for all pixels of the CCD. After frequency peak filtering followed by inverse FFT, a thermoreflectance image was obtained. The imaging results of the proposed method were quantitatively compared with those of the conventional four-bucket method, showing that the Fourier-domain filtering method can provide thermal imaging 24-42 times faster than the four-bucket method, depending on the required thermal sensitivity.

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Temperature measurements of heated microcantilevers using scanning thermoreflectance microscopy

Cited by 6 publications

References 35 publications

Measuring the surface temperature of light-emitting diodes by thermoreflectance

Measuring the surface temperature of light-emitting diodes by thermoreflectance

Electrothermal Characterization of Doped-Si Heated Microcantilevers Under Periodic Heating Operation

High-speed thermoreflectance microscopy using charge-coupled device-based Fourier-domain filtering

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