The heat equation for nanoconstrictions in 2D materials with Joule self-heating

Ward, Oliver; McCann, Edward

doi:10.1088/1361-6463/ac21fe

Cited by 3 publications

(3 citation statements)

References 72 publications

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Section: Resultsmentioning

confidence: 99%

“…For such small bias currents, this temperature increase is mostly due to Joule heating and much less due to the Peltier effect. The temperature profile due to Joule heating is given by , T ( x ) = ( F 2 k ) ( s − x ) x + T b where T b is the temperature at the boundaries just after the jumps, s is the length of the device, k is the thermal conductivity of graphene, and F = PA –1 is the Joule heating generation term. Since this equation is extracted classically from Fourier’s law and is valid in the diffusive thermal transport regime, we choose to fit only the parabolic part of the temperature profile of the suspended regime (see the curve in the gray shaded part of Figure b) excluding the mini-peaks.…”

Section: Resultsmentioning

confidence: 99%

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Thermoelectric Limitations of Graphene Nanodevices at Ultrahigh Current Densities

Evangeli,

Swett,

Spiece

et al. 2024

ACS Nano

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Graphene is atomically thin, possesses excellent thermal conductivity, and is able to withstand high current densities, making it attractive for many nanoscale applications such as field-effect transistors, interconnects, and thermal management layers. Enabling integration of graphene into such devices requires nanostructuring, which can have a drastic impact on the self-heating properties, in particular at high current densities. Here, we use a combination of scanning thermal microscopy, finite element thermal analysis, and operando scanning transmission electron microscopy techniques to observe prototype graphene devices in operation and gain a deeper understanding of the role of geometry and interfaces during high current density operation. We find that Peltier effects significantly influence the operational limit due to local electrical and thermal interfacial effects, causing asymmetric temperature distribution in the device. Thus, our results indicate that a proper understanding and design of graphene devices must include consideration of the surrounding materials, interfaces, and geometry. Leveraging these aspects provides opportunities for engineered extreme operation devices.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Thermoelectric Limitations of Graphene Nanodevices at Ultrahigh Current Densities

Evangeli,

Swett,

Spiece

et al. 2024

ACS Nano

Self Cite

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“…We have performed finite‐element simulations on the planar device geometry and found that 39% of the two‐probe resistance accounts for the central square‐shaped constriction, which is close to 47% derived by analytic expression. [ 29 ] The remaining resistance is due to the tapered NCG regions. Figure 2a shows the resistance of the device R versus the applied bias V for a substrate‐supported and suspended device.…”

Section: Resultsmentioning

confidence: 99%

Enhanced Broadband Photodetection with Geometry and Interface Engineered Nanocrystalline Graphite

Parmar,

Dehm,

Peyyety

et al. 2023

Advanced Sensor Research

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Photodetection across the near‐infrared (NIR) to short‐wavelength infrared (SWIR) spectrum is important for many applications. This study explores photodetection using nanocrystalline graphite (NCG) in a suspended, narrow constriction configuration for improved performance. Bowtie constrictions are fabricated in both suspended and substrate‐supported NCG devices, allowing for accurate comparison. It shows that the suspended constriction enhances the bolometric photoresponse and sensor detectivity by several orders of magnitude compared to the substrate‐supported counterparts, attributed to reduced thermalization and electric field concentration. The suspended configuration preserves a spectrally flat photoresponse while reducing operating voltage through a tailored NCG layer thickness. Chromatic aberration‐corrected photocurrent spectroscopy is used to measure the photoresponse from 1100 to 1700 nm, and diffraction‐limited hyperspectral photocurrent imaging is conducted to measure the local photocurrent generation across the device. Bolometric and photo‐thermoelectric currents are restricted to the suspended central constriction due to electric field concentration and thermal decoupling and the direction of the photocurrents within the sensor is revealed. The experimental data is complemented by simulations of the light absorption and the electric field distribution. This work indicates the importance of geometry and thermal decoupling for boosting device performance, offering promising prospects for sensitive and low‐power NCG‐based photodetectors in the NIR‐SWIR range.

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Multigrid method for numerical modelling of high temperature superconductors

Феодоритова

Novikova

Krasnov

et al. 2022

MathMon

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An approach to numerical simulation of three-dimensional electrical and thermal fields in high-temperature superconductors is described. In such a semiconductor, the phenomena of superconductivity are observed at high temperatures above the temperature of liquid nitrogen. The absence of a generally accepted theory of superconductivity leads to the need to study physical processes in semiconductor structures using mathematical simulations. The main attention is paid to the calculation of temperature and electric current distributions in large-size mesas with a self-heating effect. An efficient algorithm for solving the equations describing these distributions is constructed. The basis of the algorithm is an adaptive multigrid method on structured Cartesian grids. The adaptability is based on the Chebyshev iterative method for constructing the smoothing procedures at each grid level and for solving the coarsest grid equations. The adaptive technique allows us to realistically simulate the anisotropic phenomena. The functionality of the algorithm is demonstrated along with an example of solving an anisotropic model problem with discontinuous coefficients.

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The heat equation for nanoconstrictions in 2D materials with Joule self-heating

Cited by 3 publications

References 72 publications

Thermoelectric Limitations of Graphene Nanodevices at Ultrahigh Current Densities

Thermoelectric Limitations of Graphene Nanodevices at Ultrahigh Current Densities

Enhanced Broadband Photodetection with Geometry and Interface Engineered Nanocrystalline Graphite

Multigrid method for numerical modelling of high temperature superconductors

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