# I. Introduction ecause many of these components can only work properly within a relatively narrow temperature range, an entire industry has materialized that is dedicated to keeping them cool [1]. Consequently, a great deal of time and money has been spent researching the best materials for transferring energy from the delicate components and releasing it into another medium [2]. We entered this project with the goal of finding the most suitable materials for cooling semiconductor-based electrical components like CPUs. The two types of cooling methods examined are the use of heat sinks and pumped liquid cooling. First, we examine cooling systems using heat sinks. Heat sinks transfer heat from the component via conduction and release that heat in the surrounding air through both convection and radiation. The primary factor in determining the effectiveness of a material for this process is its thermal conductivity, though thermal diffusivity is also a major factor [3]. The former determines the material's ability to transfer heat away from the source while the latter speaks to its ability to move the energy throughout itself, as well as radiate it away. Usually, heat sinks are used in a forced convection system with air being moved across the heat sink fin [4]. We examined several materials for this section and have arranged them within Table_1. reminiscent of aluminum and a thermal conductivity comparable to the much heavier copper, CarbAl provides the best attributes of both materials. Its thermal diffusivity is also significantly higher than the others, allowing for better energy flux throughout itself. This material was designed in 2008 by Applied Nanotech Inc. and remains a superior material for many applications, including heat sinks for high end applications. # II. Nanofluid Simulation With regards to liquid cooling systems for semiconductor-based devices, the type of fluid plays a significant role in the transfer of energy. We selected Aluminum Oxide in a 2% solution and 40nm wide particles to simulate for our nanofluid as it is commonly used in the industry and data for it was readily available [7] [8]. The properties of the Materials used (simulated) in this study are provided in tables 2, 3 and 4. Borondoped silicon and phosphorus-doped silicon, Air, Water, Aluminum oxide nanoparticles for nanofluid. # Analysis Setup & Methodology Simulation was done using convection to transfer heat from SM to cooling fluid. Convective heat transfer coefficient (h c ) was used the principal property of fluid for simulation. We found that this coefficient depended type of medium such as gas or liquid, flow properties such as velocity, viscosity and other flow and temperature dependent properties [8]. Many of the research papers we found used other values and coefficients that are the norm in the field of thermodynamics. Nusselt, Rayleigh, and Reynolds numbers were discussed in these papers, however, since these are out of the scope of this class, we decided to use convection [12][13][14]. The terms stated above do depend on convection so it's not as to completely ignore the experimental results from researchers; convection allowed us to simplify our model. # Global Journal of Researches in # ANSYS Main purpose was to compare the cooling capabilities of air, water, and nanofluids by forced convection. Finding comparable values for the heat transfer coefficients (HTC) of each of these values was a problem, mainly because it was difficult to find experimental results that had been performed under the same conditions [12][13][14][15]. However, we were able to find papers that contained the information for water and aluminum oxide nanofluids although there were calculations needed as well as estimating values from graphs demonstrating results. These papers contained the needed coefficients for water and Al-Ox under similar conditions such as mass flow (1.5 liters per minute) and temperature (40?) therefore we could use comparable values for their respective HTCs [7,8]. A simplified geometry was used in the simulation. The actual geometry of a transistor (our example for semiconductor) was convoluted. In addition, the electronic components had to be omitted from the modeling because the focus was on thermal impact and because it was simpler to declare one region of the geometry as the heat source. Another simplification had to do with energy bands, to understand and model such concept, an understanding of Fermi function, Fermi-Dirac distribution, Boltzmann approximation, and electron concentration under different temperature conditions [12][13][14][15]. What we expected to see in the ANSYS Fluent heat maps was the heat dissipated from the source out through the boundaries making contact with the fluid. However, this was not the case the first few times that we ran the simulation. This was due to the geometry of our model; we had placed one geometry meant to represent the fluid above the geometry representing the semiconductor. There was an issue with the boundary where the surfaces met and thus, we decided to change our approach by convection. Once we read up on how convection worked, we could set up our model an analogous fashion [5]. This resulted in a simpler model where only a single geometry was needed which was meant to represent the semiconductor. Using ANSYS Fluent, the mesh was imported and given three different boundaries. The bottom edge along with both vertical edges were all labeled "outlet boundary" meaning these edges were to make contact with our test fluids (air, water, nanofluid). The top edge was the heat source; it was meant to be analogous to the conduction band on a transistor although in reality the situation is complex [15]. The surface of the body was the third boundary and this is where the properties of a semiconductor were applied to. A nanofluid composed of 98% water and 2% aluminum oxide (of particle size 40nm) showed significant improvement (Figure 3) in the rate of heat transfer over water (Figure 2) and air (Figure 1). Faiza Nazir's results showed a 200% improvement over water's rate of heat transfer [7]. # IV. Results # V. Discussion According to a handful of the research papers and experimental reports, the principal variables that accounted for the nanofluid's superior performance included: intensification of turbulence or eddy, suppression or interruption of the boundary layer as well as dispersion or back mixing of the suspended Global Journal of Researches in Engineering (A ) Volume Xx XII Issue II V ersion I nanoparticles, in addition to the nanoparticles' thermal conductivity and heat capacity [12]. # VI. Conclusion The Al 3 O 2 (40nm @ 2% volume) nanofluid had the best cooling performance of the three tested materials. 1![Figure 1: Static Temperature Contour for air with heat transfer coefficient of 1000 W/m^2-K](image-2.png "Figure 1 :") 23![Figure 2: Static Temperature Contour for Water with heat transfer coefficient of 3000 W/m^2-K](image-3.png "Figure 2 :Figure 3 :") 1Year 202221(A ) Volume Xx XII Issue II V ersion IGlobal Journal of Researches in EngineeringUSA. e-mail: hghasemi@sdccd.edu Author ?: Mechanical Engineering Department, Shahid Beheshti University, Tehran, Iran. 2 3 4 Year 2022 © 2022 Global Journals Numerical Thermal Stress Analysis on Semiconductors with Nano-Fluid Coolant © 2022 Global Journals Numerical Thermal Stress Analysis on Semiconductors with Nano-Fluid Coolant * National Advisory Committee for Aeronautics Report 1170 * Calculation of Semiconductor Failure Rates by William J. Vigrass * Thermal Conductivity of common Materials and Gases * Heat Transfer of Aluminium-Oxide Nanofluids in a Compact Heat Exchanger FMNasir Applied Mechanics and Materials, Vols 2014 * Investigation on Convective Heat Transfer and Flow Features of Nanofluids Yimin &Xuan QiangLi 125. 10.1115/1. 1532008 2003 Journal of Heat Transfer-transactions of The Asme -J HEAT TRANSFER * SkySpring Nanomaterials Tin Oxide Nanoparticles 0 * Inc Silicon Oxide Spherical Powder 0 US Research Nanomaterials * Aluminum Oxide Nanofluid Energy Transfer RAghayari HMaddah ZSharifnezhad AHakiminejad SSarli 10.7508/tpnms.2015.01.006 Transp Phenom Nano Micro Scales 3 1 2015 * Engineering Applications of Nanotechnology 10.1007/978-3-319-29761-3_2 Topics in Mining, Metallurgy and Materials Engineering K ViswanathaSharma NHisham Hamid * Experimental Measurements of Nanofluids Thermal Properties MAdnan RAHusein KBakar KVKadirgama Sharma International Journal of Automotive and Mechanical Engineering 1985- 9325 7 2013 Online Print * 10.1063/1.1458057 Journal of Applied Physics 91 5079 2002