(a) Explanation Calculation: Write the relation between E , G, k and Poisson’s ratio ( ν ): Refer to Equation 2.24 in the textbook. k = E 3 ( 1 − 2 ν ) (1) Here, ν is Poisson’s ratio. Refer to Equation 2.35 in the textbook. G = E 2 ( 1 + ν ) (2) Refer to Equation 2.34 in the textbook. E 2 G = 1 + ν v = E 2 G − 1 Substitute E 2 G − 1 for ν in Equation (1). k = E 3 ( 1 − 2 ( E 2 G − 1 ) ) (b) To determine Prove the relation between young’s modulus ( E ), bulk modulus ( k ), Poisson’s ratio ( ν ) and modulus of rigidity ( G ), as ν = ( 3 k − 2 G ) ( 6 k + 2 G )

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Author: BEER

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Chapter 2.9, Problem 89P

(a)

To determine

Prove the relation between young’s modulus (E), bulk modulus (k), and modulus of rigidity (G) as k=GE(9G−3E)

(b)

To determine

Prove the relation between young’s modulus (E), bulk modulus (k), Poisson’s ratio (ν) and modulus of rigidity (G), as ν=(3k−2G)(6k+2G)

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Chapter 2.9, Problem 88P

Chapter 2.9, Problem 90P

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Chapter 2 Solutions

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Prove the relation between young’s modulus ( E ), bulk modulus ( k ), and modulus of rigidity ( G ) as k = G E ( 9 G − 3 E )

Solution Summary: The author explains how to prove the relation between E, bulk modulus, and rigidity.

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Prove the relation between young’s modulus (E), bulk modulus (k), and modulus of rigidity (G) as k=GE(9G−3E)

Prove the relation between young’s modulus (E), bulk modulus (k), Poisson’s ratio (ν) and modulus of rigidity (G), as ν=(3k−2G)(6k+2G)

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Chapter 2 Solutions