7th Edition

ISBN: 9780470917855

Author: Bergman, Theodore L./

Publisher: John Wiley & Sons Inc

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When energy travels from one object to another it is said to have undergone heat transfer. Heat transfer is nothing but the transfer of thermal energy or internal energy from one thing to another, like e.g., when a vessel with water, kept on top of a bur…

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Textbook Question

Chapter 3, Problem 3.145P

As seen in Problem 3.109, silicon carbide nanowires of diameter D = 15 nm can be grown onto a solid silicon carbide surface by carefully depositing droplets of catalyst liquid onto a flat silicon carbide substrate. Silicon carbide nanowires grow upward from the deposited drops, and if the drops are deposited in a pattern, an array of nanowire tins can be grown, forming a silicon carbide nano-heat sink. Consider tinned and untinned electronics packages in which an extremely small, 10 μm × 10 μm electronics device is sandwiched between two d = 100 -nm-thick silicon carbide sheets. In both cases, the coolant is a dielectric liquid at 20°C. A heat transfer coefficient of h = 1 × 10 5 W/m 2 ⋅ K exists on the top and bottom of the unfinned package and on all surfaces of the exposed silicon carbide tins. which are each L = 300 nm long. Each nano-heat sink includes a 200 × 200 array of nanofins. Determine the maximum allowable heat rate that can be generated by the electronic device so that its temperature is maintained at T t < 85 ° C for the untinned and tinned packages.

Chapter 3, Problem 3.145P, As seen in Problem 3.109, silicon carbide nanowires of diameter D=15nm can be grown onto a solid

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Chapter 3, Problem 3.144P

Chapter 3, Problem 3.147P

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Chapter 3 Solutions

Fundamentals of Heat and Mass Transfer

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Solution Summary: The author calculates the maximum allowable heat rate that can be generated by the electronic device. The temperature of the dielectric liquid used as coolant = 20 o C.

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Chapter 3 Solutions