Higher Education

Mechanics of Materials, SI Edition, 8th Edition

  • James M. Gere (deceased)
  • Barry J. Goodno Georgia Institute of Technology
  • ISBN-10: 1111577749  |  ISBN-13: 9781111577742
  • 1056 Pages
  • Previous Editions: 2009, 2006
  • © 2013 | Published
  • College Bookstore Wholesale Price = $173.25
  • Newer Edition Available
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About

Overview

The Eighth Edition of MECHANICS OF MATERIALS continues its tradition as one of the leading texts on the market. With its hallmark clarity and accuracy, this text develops student understanding along with analytical and problem-solving skills. The main topics include analysis and design of structural members subjected to tension, compression, torsion, bending, and more. The book includes more material than can be taught in a single course giving instructors the opportunity to select the topics they wish to cover while leaving any remaining material as a valuable student reference.

Features and Benefits

  • 4-color format provides better visualization of graphs and worked out problems.
  • Clarity and accuracy: Considerable effort was spent in designing, checking, and proofreading the text and figures.
  • Problems: The text offers more than 1000 problems for homework assignments and classroom discussions. The exercises are arranged in order of difficulty and placed at the end of the chapter making them easy to find without breaking up the subject matter.
  • Examples: Numerous examples illustrate the theoretical concepts and show how those concepts may be used in practical situations. In some cases, photographs have been added showing actual engineering structures or components to reinforce the tie between theory and application.

Table of Contents

1. TENSION, COMPRESSION, AND SHEAR.
Introduction to Mechanics of Material. Statics Review. Normal Stress and Strain. Mechanical Properties of Materials. Elasticity, Plasticity, and Creep. Linear Elasticity, Hooke''s Law, and Poisson''s Ratio. Shear Stress and Strain. Allowable Stresses and Allowable Loads. Design for Axial Loads and Direct Shear.
2. AXIALLY LOADED MEMBERS.
Introduction. Changes in lengths of Axially Loaded Members. Changes in Lengths under Nonuniform Conditions. Statically Indeterminate Structures. Thermal Effects, Misfits, and Prestrains. Stresses on Inclined Sections. Strain Energy. Impact Loading. Repeated Loading and Fatigue. Stress Concentrations. Nonlinear Behavior. Elastoplastic Analysis.
3. TORSION.
Introduction. Torsional Deformations of a Circular Bar. Circular Bars of Linearly Elastic Materials. Nonuniform Torsion. Stresses and Strains in Pure Shear. Relationship Between Moduli of Elasticity E and G. Transmission of Power by Circular Shafts. Statically Indeterminate Torsional Members. Strain Energy in Torsion and Pure Shear. Torsion of Noncircular Prismatic Shafts. Thin-Walled Tubes. Stress Concentration in Torsion.
4. SHEAR FORCES AND BENDING MOMENTS.
Introduction. Types of Beams, Loads, and Reactions. Shear Forces and Bending Moments. Relationship Between Loads, Shear Forces and Bending Moments. Shear-Force and Bending-Moment Diagrams.
5. STRESSES IN BEAMS (BASIC TOPICS).
Introduction. Pure Bending and Nonuniform Bending. Curvature of Beam. Longitudinal Strains in Beams. Normal Stress in Beams (Linearly Elastic Materials). Design of Beams for Bending Stresses. Nonprismatic Beams. Shear Stresses in Beams of Rectangular Cross Section. Shear Stresses in Beams of Circular Cross Section. Shear Stresses in the Webs of Beams with Flanges. Built-Up Beams and Shear Flow. Beams with Axial Loads. Stress Concentrations in Bending.
6. STRESSES IN BEAMS (ADVANCED TOPICS).
Introduction. Composite Beams. Transformed-Section Method. Doubly Symmetric Beams with Inclined Loads. Bending of Unsymmetric Beams. The Shear-Center Concept. Shear Stresses in Beams of Thin-Walled Open Cross Sections. Shear Stresses in Wide-Flange Beams. Shear Centers of Thin-Walled Open Sections. Elastoplastic Bending.
7. ANALYSIS OF STRESS AND STRAIN.
Introduction. Plane Stress. Principal Stresses and Maximum Shear Stresses. Mohr''s Circle for Plane Stress. Hooke''s Law for Plane Stress. Triaxial Stress. Plane Strain.
8. APPLICATIONS OF PLANE STRESS (PRESSURE VESSELS, BEAMS, AND COMBINED LOADINGS).
Introduction. Spherical Pressure Vessels. Cylindrical Pressure Vessels. Maximum Stresses in Beams. Combined Loadings.
9. DEFLECTIONS OF BEAMS.
Introduction. Differential Equations of the Deflection Curve. Deflections by Integration of the Bending-Moment Equation. Deflections by Integration of the Shear-Force and Load Equations. Method of Superposition. Moment-Area Method. Nonprismatic Beams. Strain Energy of Bending. Castigliano''s Theorem. Deflections produced by Impact. Temperature Effects.
10. STATICALLY INDETERMINATE BEAMS.
Introduction. Types of Statically Indeterminate Beams. Analysis by the Differential Equations of the Deflection Curve. Method of Superposition. Temperature Effects. Longitudinal Displacements at the End of a Beam.
11. COLUMNS.
Introduction. Buckling and Stability. Columns with Pinned Ends. Columns with Other Support Conditions. Columns with Eccentric Axial Loads. The Secant Formula for Columns. Elastic and Inelastic Column Behavior. Inelastic Buckling. Design Formulas for Columns.
12. REVIEW OF CENTROIDS AND MOMENTS OF INERTIA.
Introduction. Centroids of Plane Areas. Centroids of Composite Areas. Moments of Inertia of Plane Areas. Parallel-Axis Theorem for Moments of Inertia. Polar Moments of Inertia. Products of Inertia. Rotation of Axes. Principal Axes and Principal Moments of Inertia.
REFERENCES AND HISTORICAL NOTES.
APPENIDX A. FE EXAM REVIEW PROBLEMS.
APPENDIX B. PROBLEM SOLVING.
APPENDIX C. MATHEMATICAL FORMULAS.
APPENDIX D. PROPERTIES OF PLANE AREAS.
APPENDIX E. PROPERTIES OF STRUCTURAL-STEEL SHAPES.
APPENDIX F. PROPERTIES OF STRUCTURAL LUMBER.
APPENDIX G. DEFLECTION AND SLOPES OF BEAMS.
APPENDIX H. PROPERTIES OF MATERIALS.

What's New

  • Learning objectives have been added to the beginning of each chapter.
  • Chapter Overview sections have been updated with all important concepts highlighted.
  • Updated Chapter Summary and Review sections at the end of each chapter now include key formulas derived, discussed and applied to problem solutions.
  • An enhanced step-by-step solution approach has been implemented so that important fundamental concepts can be highlighted and emphasized.
  • Over 100 new problems typical in type and format of those found on the FE Examination have been added in an additional appendix to assist students in preparing for the FE Exam.
  • All problems have been reviewed for appropriateness and accuracy; many were revised or updated to improve clarity in presentation of fundamental concepts; in some cases, problem solutions were revised to enhance learning.
  • New section added to Chapter 1 to assist the student in making the transition from the prerequisite course on Statics to Mechanics of Materials; fundamental concepts of equilibrium are reviewed and then applied to solution of sample problems like those they will encounter in later chapters.
  • Many new/updated/revised example problems have been added in each chapter; some are based on actual structures and photos have been added where appropriate.

Efficacy and Outcomes

Reviews

"The authors do and excellent job of discussing the topics at a level I believe will be absorbed by the students. They also make a good effort to highlight the important issues and points in the text by italicizing or bolding. I feel that the author has done an excellent job of relating real structures to solid body analysis techniques, and haspresented and discussed it in a manner that I think students will appreciate."

— Dr. Douglas P. Romilly, University of British Columbia

"The homework problems are perhaps the strongest point of the text. The problems cover the waterfront in variety, complexity and coverage. They include numerous examples that are found inthe real world and students can identify with them."

— Edward Tezak, Alfred State College

"The books strongest feature is the comprehensive coverage and reasonableness of the homework problems in establishing a base of understanding of expected levels of stress, strain, and displacement."

— Henry N. Christiansen, Brigham Young University

"The author has done an excellent job conveying the concepts. The textbook is easy to follow and all the ideas are clearly presented."

— Lun-Shin Yao, Arizona State University

"This is a detailed overview of undergraduate solid mechanics. It is an excellent book, and far superior to current texts, which borrowed extensively from Gere."

— Mohammed Zikry, North Carolina State University

Supplements

All supplements have been updated in coordination with the main title. Select the main title's "About" tab, then select "What's New" for updates specific to title's edition.

For more information about these supplements, or to obtain them, contact your Learning Consultant.

Instructor Supplements

CengageNOW Instant Access, SI Edition  (ISBN-10: 1133508812 | ISBN-13: 9781133508816)

List Price = $187.95  | CengageBrain Price = $187.95  | College Bookstore Wholesale Price = $141.50

Instructor Solutions Manual, SI Edition  (ISBN-10: 1111578583 | ISBN-13: 9781111578589)

Includes solutions to all problems from the text. Rotated stress elements for problems are also included as well as an increased number of FBDs.

Student Supplements

CengageNOW Instant Access, SI Edition  (ISBN-10: 1133508812 | ISBN-13: 9781133508816)

Succeed in your automotive course with CengageNOW™, a powerful online homework tool that optimizes your learning experience. This interactive system generates a diagnostic Personalized Study Plan (with a chapter-specific Pre-test, Study Plan, and Post-test) to help you master concepts, prepare for exams, and get a better grade.

List Price = $187.95  | CengageBrain Price = $187.95  | College Bookstore Wholesale Price = $141.50

Meet the Author

Author Bio

James M. Gere

James M. Gere (1925-2008) earned his undergraduate and master’s degrees in Civil Engineering from the Rensselaer Polytechnic Institute, where he worked as instructor and Research Associate. He was awarded one of the first NSF Fellowships and studied at Stanford, where he earned his Ph.D. He joined the faculty in Civil Engineering, beginning a 34-year career of engaging his students in mechanics, structural and earthquake engineering. He served as Department Chair and Associate Dean of Engineering and co-founded the John A. Blume Earthquake Engineering Center at Stanford. Dr. Gere also founded the Stanford Committee on Earthquake Preparedness. He was one of the first foreigners invited to study the earthquake-devastated city of Tangshan, China. Dr. Gere retired in 1988 but continued to be an active, valuable member of the Stanford community. Dr. Gere was known for his cheerful personality, athleticism, and skill as an educator. He authored nine texts on engineering subjects starting with Mechanics of Materials, a text that was inspired by his teacher and mentor Stephan P. Timoshenko. His other well-known textbooks, used in engineering courses around the world, include: Theory of Elastic Stability, co-authored with S. Timoshenko; Matrix Analysis of Framed Structures and Matrix Algebra for Engineers, both co-authored with W. Weaver; Moment Distribution; Earthquake Tables: Structural and Construction Design Manual, co-authored with H. Krawinkler; and Terra Non Firma: Understanding and Preparing for Earthquakes, co-authored with H. Shah. In 1986 he hiked to the base camp of Mount Everest, saving the life of a companion on the trip. An avid runner, Dr. Gere completed the Boston Marathon at age 48 in a time of 3:13. Dr. Gere is remembered as a considerate and loving man whose upbeat humor always made aspects of daily life and work easier.

Barry J. Goodno

Barry John Goodno is Professor of Civil and Environmental Engineering at Georgia Institute of Technology. He joined the Georgia Tech faculty in 1974. He was an Evans Scholar and received a B.S. in Civil Engineering from the University of Wisconsin, Madison, Wisconsin, in 1970. He received M.S. and Ph.D. degrees in Structural Engineering from Stanford University, Stanford, California, in 1971 and 1975, respectively. He holds a professional engineering license (PE) in Georgia, is a Distinguished Member of ASCE and an Inaugural Fellow of SEI, and has held numerous leadership positions within ASCE. He is a member of the Engineering Mechanics Institute (EMI) of ASCE and is a past president of the ASCE Structural Engineering Institute (SEI) Board of Governors. He is past-chair of the ASCE-SEI Technical Activities Division (TAD) Executive Committee, and past-chair of the ASCE-SEI Awards Committee. In 2002, Dr. Goodno received the SEI Dennis L. Tewksbury Award for outstanding service to ASCE-SEI. He received the departmental award for Leadership in Use of Technology in 2013 for his pioneering use of lecture capture technologies in undergraduate statics and mechanics of materials courses at Georgia Tech. He is a member of the Earthquake Engineering Research Institute (EERI) and has held several leadership positions within the NSF-funded Mid-America Earthquake Center (MAE), directing the MAE Memphis Test Bed Project. Dr. Goodno has carried out research, taught graduate courses and published extensively in the areas of earthquake engineering and structural dynamics during his tenure at Georgia Tech. Dr. Goodno is an active cyclist, retired soccer coach and referee, and a retired marathon runner. Like co-author and mentor James Gere, he has completed numerous marathons including qualifying for and running the Boston Marathon in 1987.