Mechanics of Materials Plus Mastering Engineering with Pearson eText -- Access Card Package

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  • Edition: 10th
  • Format: Package
  • Copyright: 2016-05-18
  • Publisher: Pearson

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For undergraduate Mechanics of Materials courses in Mechanical, Civil, and Aerospace Engineering departments.

This package includes MasteringEngineering™.


Thorough coverage, a highly visual presentation, and increased problem solving from an author you trust.

Mechanics of Materials clearly and thoroughly presents the theory and supports the application of essential mechanics of materials principles. Professor Hibbeler’s concise writing style, countless examples, and stunning four-color photorealistic art program — all shaped by the comments and suggestions of hundreds of reviewers — help readers visualize and master difficult concepts. The Tenth Edition retains the hallmark features synonymous with the Hibbeler franchise, but has been enhanced with the most current information, a fresh new layout, added problem solving, and increased flexibility in the way topics are covered.


Personalize learning with MasteringEngineering.

MasteringEngineering is an online homework, tutorial, and assessment program designed to work with this text to engage students and improve results. Interactive, self-paced tutorials provide individualized coaching to help students stay on track. With a wide range of activities available, students can actively learn, understand, and retain even the most difficult concepts. The text and MasteringEngineering work together to guide students through engineering concepts with a multi-step approach to problems.


0134518128 / 9780134518121     Mechanics of Materials Plus MasteringEngineering with Pearson eText -- Access Card Package, 10/e


Package consists of:

  • 0134319656 / 9780134319650      Mechanics of Materials, 10/e
  • 0134321286 / 9780134321288      MasteringEngineering with Pearson eText--Standalone Access Card--for Mechanics of Materials



Author Biography

R.C. Hibbeler graduated from the University of Illinois at Urbana with a BS in Civil Engineering (majoring in Structures) and an MS in Nuclear Engineering. He obtained his PhD in Theoretical and Applied Mechanics from Northwestern University. Professor Hibbeler’s professional experience includes postdoctoral work in reactor safety and analysis at Argonne National Laboratory, and structural and stress analysis work at Chicago Bridge and Iron, as well as at Sargent and Lundy in Chicago. He has practiced engineering in Ohio, New York, and Louisiana.


Professor Hibbeler currently teaches both civil and mechanical engineering courses at the University of Louisiana– Lafayette. In the past, he has taught at the University of Illinois at Urbana, Youngstown State University, Illinois Institute of Technology, and Union College.


Table of Contents


1. Stress

Chapter Objectives   

1.1          Introduction

1.2          Equilibrium of a Deformable Body

1.3          Stress

1.4          Average Normal Stress in an Axially Loaded Bar   

1.5          Average Shear Stress   

1.6          Allowable Stress Design   

1.7          Limit State Design   


2. Strain

Chapter Objectives   

2.1          Deformation

2.2          Strain


3. Mechanical Properties of Materials

Chapter Objectives

3.1          The Tension and Compression Test

3.2          The Stress—Strain Diagram

3.3          Stress—Strain Behavior of Ductile and Brittle Materials    

3.4          Strain Energy

3.5          Poisson’s Ratio   

3.6          The Shear Stress—Strain Diagram    

*3.7        Failure of Materials Due to Creep and Fatigue   


4. Axial Load

Chapter Objectives   

4.1          Saint-Venant’s Principle    

4.2          Elastic Deformation of an Axially Loaded Member

4.3          Principle of Superposition   

4.4          Statically Indeterminate Axially Loaded Members

4.5          The Force Method of Analysis for Axially Loaded Members   

4.6          Thermal Stress   

4.7          Stress Concentrations    

*4.8         Inelastic Axial Deformation   

*4.9         Residual Stress   


5. Torsion

Chapter Objectives

5.1          Torsional Deformation of a Circular Shaft

5.2          The Torsion Formula    

5.3          Power Transmission   

5.4          Angle of Twist   

5.5          Statically Indeterminate Torque-Loaded Members

*5.6        Solid Noncircular Shafts   

*5.7        Thin-Walled Tubes Having Closed Cross Sections

5.8          Stress Concentration   

*5.9        Inelastic Torsion   

*5.10      Residual Stress    


6. Bending

Chapter Objectives   

6.1          Shear and Moment Diagrams   

6.2          Graphical Method for Constructing Shear and Moment Diagrams   

6.3          Bending Deformation of a Straight Member

6.4          The Flexure Formula

6.5          Unsymmetric Bending

*6.6        Composite Beams

*6.7        Reinforced Concrete Beams

*6.8        Curved Beams

6.9          Stress Concentrations

*6.10      Inelastic Bending


7. Transverse Shear

Chapter Objectives

7.1          Shear in Straight Members

7.2          The Shear Formula

7.3          Shear Flow in Built-Up Members

7.4          Shear Flow in Thin-Walled Members

*7.5        Shear Center for Open Thin-Walled Members


8. Combined Loadings

Chapter Objectives

8.1          Thin-Walled Pressure Vessels

8.2          State of Stress Caused by Combined Loadings


9. Stress Transformation

Chapter Objectives

9.1          Plane-Stress Transformation

9.2          General Equations of Plane-Stress Transformation

9.3          Principal Stresses and Maximum In-Plane Shear Stress

9.4          Mohr’s Circle–Plane Stress

9.5          Absolute Maximum Shear Stress


10. Strain Transformation

Chapter Objectives

10.1        Plane Strain

10.2        General Equations of Plane-Strain Transformation

*10.3      Mohr’s Circle–Plane Strain

*10.4      Absolute Maximum Shear Strain

10.5        Strain Rosettes

10.6        Material Property Relationships

*10.7      Theories of Failure


11. Design of Beams and Shafts

Chapter Objectives

11.1        Basis for Beam Design

11.2        Prismatic Beam Design

*11.3      Fully Stressed Beams

*11.4      Shaft Design


12. Deflection of Beams and Shafts

Chapter Objectives

12.1        The Elastic Curve

12.2        Slope and Displacement by Integration

*12.3      Discontinuity Functions

*12.4      Slope and Displacement by the Moment-Area Method

12.5        Method of Superposition

12.6        Statically Indeterminate Beams and Shafts

12.7        Statically Indeterminate Beams and Shafts–Method of Integration

*12.8      Statically Indeterminate Beams and Shafts–Moment-Area Method

12.9        Statically Indeterminate Beams and Shafts–Method of Superposition


13. Buckling of Columns

Chapter Objectives

13.1        Critical Load

13.2        Ideal Column with Pin Supports

13.3        Columns Having Various Types of Supports

*13.4      The Secant Formula

*13.5      Inelastic Buckling

*13.6      Design of Columns for Concentric Loading

*13.7      Design of Columns for Eccentric Loading


14. Energy Methods

Chapter Objectives

14.1        External Work and Strain Energy

14.2        Elastic Strain Energy for Various Types of Loading

14.3        Conservation of Energy

14.4        Impact Loading

*14.5      Principle of Virtual Work

*14.6      Method of Virtual Forces Applied to Trusses

*14.7      Method of Virtual Forces Applied to Beams

*14.8      Castigliano’s Theorem

*14.9      Castigliano’s Theorem Applied to Trusses

*14.10    Castigliano’s Theorem Applied to Beams



A             Geometric Properties of an Area

B             Geometric Properties of Structural Shapes

C             Slopes and Deflections of Beams


Solutions and Answers for Preliminary Problems

Fundamental Problems Partial Solutions and Answers

Selected Answers



Sections of the book that contain more advanced material are indicated by a star (*).


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