The accuracy of the classical heat conduction model, known as Fourier's law, is highly
questioned, dealing with the micro-and nanosystems and biological tissues. In other words …

The study of heat transport in micro/nanoscale structures due to their application, especially
in Nanoelectronics, is a matter of interest. In other words, the precise simulation of the …

In the progressive miniaturization of graphene field-effect transistors (GrFETs), pronounced
thermal boundary resistance (TBR) and increasing ballistic-diffusive thermal resistance pose …

The diffusion of gas molecules on multilayer graphene surfaces is of great importance for a
wide range of applications in gas-related industries. This study calculates diffusion …

Thermal transport in the Metal Oxide Semiconductor Field Effect Transistor (MOSFET) has
received increased attention across a number of disciplines in recent years. One of the most …

Graphene, with its exceptional thermal conductivity and electron mobility, is widely
recognized as a potential candidate for next-generation transistor materials. Despite the lack …

Thermal diffusion in the metal oxide semiconductor field effect transistor has received
increased attention across a number of disciplines in recent years. This paper studies a …

It is commonly believed that the significant energy saving advantages are belonged to the
logic circuits which operate at low temperature as less energy is needed for cooling them to …

The accuracy of the classical heat conduction model, known as Fourier's law, is highly
questioned, dealing with the micro/nanosystems and biological tissues. In other words, the …

The non-Fourier dual-phase-lag heat model has been solved as a well-known accurate
bioheat model to compute the temperature distribution in a three-dimensional multilayered …