Methods for topography artifacts compensation in scanning thermal microscopy

Martínek, Jan; Klapetek, Petr; Campbell, Anna Charvátová

doi:10.1016/j.ultramic.2015.04.011

Cited by 28 publications

(18 citation statements)

References 14 publications

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“…It is also worth pointing out here that these considerations are reliable and are correctly related to the thermal properties of the materials under study only when the tip is scanned over a rather flat surface (compared to the probe apex height). Indeed, if the topology is highly irregular, the measured temperature can be strongly affected by topological effects [ 43 ]. For example, if the tip is being scanned on the top of a rather high "hill", the temperature measured by the sensor will be much higher than the actual temperature of the surface which can thus be overestimated due to the fact that a smaller sample area is heated by the probe, either because it is surrounded by more air (yielding a bad conduction) and/or because the tip-sample contact area decreases with respect to an ideal probed flat region.…”

Section: Let Us First Recall That the Thermal Resistance Is Defined Asmentioning

confidence: 99%

Effect of thermal annealing on the heat transfer properties of reduced graphite oxide flakes: A nanoscale characterization via scanning thermal microscopy

Tortello

Colonna

Bernal

et al. 2016

Carbon

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This paper reports on the thermal properties of reduced graphite oxide (RGO) flakes, studied by means of scanning thermal microscopy (SThM). This technique was demonstrated to allow thermal characterization of the flakes with a spatial resolution of the order of a few tens of nanometers, while recording nanoscale topography at the same time. Several individual RGO flakes were analyzed by SThM, both as obtained after conventional thermal reduction and after a subsequent annealing at 1700°C. Significant differences in the thermal maps were observed between pristine and annealed flakes, reflecting higher heat dissipation on annealed RGO flakes compared with pristine ones. This result was correlated with the reduction of RGO structure defectiveness. In particular, a substantial reduction of oxidized groups and sp 3 carbons upon annealing was proven by X-ray photoelectron and Raman spectroscopies, while the increase of crystalline order was demonstrated by X-ray diffraction, in terms of higher correlation lengths both along and perpendicular to the graphene planes. Results presented in this paper provide experimental evidence for the qualitative correlation between the defectiveness of graphene-related materials and their thermal conductivity, which is clearly crucial for the exploitation of these materials into thermally conductive nanocomposites.©2016. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/

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Section: Let Us First Recall That the Thermal Resistance Is Defined Asmentioning

confidence: 99%

Effect of thermal annealing on the heat transfer properties of reduced graphite oxide flakes: A nanoscale characterization via scanning thermal microscopy

Tortello

Colonna

Bernal

et al. 2016

Carbon

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“…Sharp changes in relief would affect the contact area and, thus, the heat exchange between tip and sample, which would falsify the thermal image. Martinek et al [20] used nethods, such as neural network analysis and three-dimensional (3D) finite element modelling, to reduce this topography influence. An excellent overview about the fundamentals and applications of SThM is given in the review of Gomès et al [21].…”

Section: Introductionmentioning

confidence: 99%

On the Limits of Scanning Thermal Microscopy of Ultrathin Films

et al. 2020

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Heat transfer processes in micro- and nanoscale devices have become more and more important during the last decades. Scanning thermal microscopy (SThM) is an atomic force microscopy (AFM) based method for analyzing local thermal conductivities of layers with thicknesses in the range of several nm to µm. In this work, we investigate ultrathin films of hexagonal boron nitride (h-BN), copper iodide in zincblende structure (γ-CuI) and some test sample structures fabricated of silicon (Si) and silicon dioxide (SiO2) using SThM. Specifically, we analyze and discuss the influence of the sample topography, the touching angle between probe tip and sample, and the probe tip temperature on the acquired results. In essence, our findings indicate that SThM measurements include artefacts that are not associated with the thermal properties of the film under investigation. We discuss possible ways of influence, as well as the magnitudes involved. Furthermore, we suggest necessary measuring conditions that make qualitative SThM measurements of ultrathin films of h-BN with thicknesses at or below 23 nm possible.

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“…To address the lack of versatile, high-resolution thermometry techniques, scanning probe-based methods have been explored 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 . Thermal scanning probe measurements, however, typically suffer from contact-related artefacts 13 14 29 30 that restrict their applicability for nanoscale thermometry.…”

mentioning

confidence: 99%

“…Unlike macroscopic contact thermometers, they typically not infer temperature by measuring only one physical property, for example, the electrical resistance, of a calibrated sensor in equilibrium with the system of interest. Instead, they detect a heat-flux-related signal across a tip–sample contact that is not only proportional to the temperature difference between a probe sensor ( T sensor ) and a sample ( T sample ), but also influenced by an unknown thermal contact resistance ( R ts ( T )) 29 30 . The well-established concept of equilibrium contact thermometry cannot be easily adapted to the nanoscale, as it would require R ts to be small compared with the resistance between the sensor and its thermal reservoir ( R cl ), a condition that practically cannot be achieved for high-resolution scanning probes forming nanoscopic contacts 18 19 22 23 24 25 .…”

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confidence: 99%

Temperature mapping of operating nanoscale devices by scanning probe thermometry

et al. 2016

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Imaging temperature fields at the nanoscale is a central challenge in various areas of science and technology. Nanoscopic hotspots, such as those observed in integrated circuits or plasmonic nanostructures, can be used to modify the local properties of matter, govern physical processes, activate chemical reactions and trigger biological mechanisms in living organisms. The development of high-resolution thermometry techniques is essential for understanding local thermal non-equilibrium processes during the operation of numerous nanoscale devices. Here we present a technique to map temperature fields using a scanning thermal microscope. Our method permits the elimination of tip-sample contact-related artefacts, a major hurdle that so far has limited the use of scanning probe microscopy for nanoscale thermometry. We map local Peltier effects at the metal-semiconductor contacts to an indium arsenide nanowire and self-heating of a metal interconnect with 7 mK and sub-10 nm spatial temperature resolution.

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Methods for topography artifacts compensation in scanning thermal microscopy

Cited by 28 publications

References 14 publications

Effect of thermal annealing on the heat transfer properties of reduced graphite oxide flakes: A nanoscale characterization via scanning thermal microscopy

Effect of thermal annealing on the heat transfer properties of reduced graphite oxide flakes: A nanoscale characterization via scanning thermal microscopy

On the Limits of Scanning Thermal Microscopy of Ultrathin Films

Temperature mapping of operating nanoscale devices by scanning probe thermometry

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