Introduction To Nuclear Engineering by John R. LamarshIntroduction To Nuclear Engineering by John R. Lamarsh

Introduction To Nuclear Engineering

byJohn R. Lamarsh, Anthony J. Baratta

Hardcover | January 9, 2017

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For junior- and senior-level courses in Nuclear Engineering.


Applying nuclear engineering essentials to the modern world

Introduction to Nuclear Engineering , 4th Edition reflects changes in the industry since the 2001 publication of its predecessor. With recent data and information, including expanded discussions about the worldwide nuclear renaissance and the development and construction of advanced plant designs, the text aims to provide students with a modern, high-level introduction to nuclear engineering. The nuclear industry is constantly in flux, and the 4th Edition helps students understand real-world applications of nuclear technology—in the United States and across the globe.

John R. Lamarsh (deceased) was the head of the nuclear engineering department at the Polytechnic Institute of New York (now the New York University Tandon School of Engineering). He was considered an expert on nuclear energy policy and safety, nuclear weapons proliferation, and was appointed administrative judge of the Federal Nuclea...
Title:Introduction To Nuclear EngineeringFormat:HardcoverDimensions:816 pages, 9.4 × 7.35 × 1.9 inPublished:January 9, 2017Publisher:Pearson EducationLanguage:English

The following ISBNs are associated with this title:

ISBN - 10:0134570057

ISBN - 13:9780134570051

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Table of Contents

1. Nuclear Engineering


2. Atomic and Nuclear Physics

2.1 Fundamental Particles

2.2 Atomic and Nuclear Structures

2.3 Atomic and Molecular Weights

2.4 Atomic and Nuclear Radii

2.5 Mass and Energy

2.6 Particle Wavelengths

2.7 Excited States and Radiation

2.8 Nuclear Stability and Radioactive Decay

2.9 Radioactivity Calculations

2.10 Nuclear Reactions

2.11 Binding Energy

2.12 Nuclear Models

2.13 Gases, Liquids, and Solids

2.14 Atom Density




3. Interaction of Radiation with Matter

3.1 Neutron Interactions

3.2 Cross Sections

3.3 Neutron Attenuation

3.4 Neutron Flux

3.5 Neutron Cross Section Data

3.6 Energy Loss in Scattering Collisions

3.7 Fission

3.8 y-Ray Interactions with Matter

3.9 Charged Particles




4. Nuclear Reactors and Nuclear Power

4.1 The Fission Chain Reaction

4.2 Nuclear Reactor Fuels

4.3 Non-Nuclear Components of Nuclear Power Plants

4.4 Components of Nuclear Reactors

4.5 Power Reactors and Nuclear Steam Supply Systems

4.6 Nuclear Cycles

4.7 Isotope Separation

4.8 Fuel Reprocessing

4.9 Radioactive Waste Disposal




5. Neutron Diffusion and Moderation

5.1 Neutron Flux

5.2 Fick’s Law

5.3 The Equation of Continuity

5.4 The Diffusion Equation

5.5 Boundary Conditions

5.6 Solutions of the Diffusion Equation

5.7 The Diffusion Length

5.8 The Group-Diffusion Method

5.9 Thermal Neutron Diffusion

5.10 Two-Group Calculation of Neutron Moderation




6. Nuclear Reactor Theory

6.1 One-Group Reactor Equation

6.2 The Slab Reactor

6.3 Other Reactor Shapes

6.4 The One-Group Critical Equation

6.5 Thermal Reactors

6.6 Reflected Reactors

6.7 Multigroup Calculations

6.8 Heterogeneous Reactors




7. The Time-Dependent Reactor

7.1 Classification of Time Problems

7.2 Reactor Kinetics

7.3 Control Rods and Chemical Shim

7.4 Temperature Effects on Reactivity

7.5 Fission Product Poisoning

7.6 Core Properties During Lifetime




8. Heat Removal from Nuclear Reactors

8.1 General Thermodynamic Considerations

8.2 Heat Generation in Reactors

8.3 Heat Flow by Conduction

8.4 Heat Transfer to Coolants

8.5 Boiling Heat Transfer

8.6 Thermal Design of a Reactor




9. Radiation Protection

9.1 History of Radiation Effects

9.2 Radiation Units

9.3 Some Elementary Biology

9.4 The Biological Effects of Radiation

9.5 Quantitative Effects of Radiation on the Human Species

9.6 Calculations of Radiation Effects

9.7 Natural and Man-Made Radiation Sources

9.8 Standards of Radiation Protection

9.9 Computations of Exposure and Dose

9.10 Standards for Intake of Radionuclides

9.11 Exposure from y-Ray Sources





10. Radiation Shielding

10.1 Gamma-Ray Shielding: Buildup Factors

10.2 Infinite Planar and Disc Sources

10.3 The Line Source

10.4 Internal Sources

10.5 Multilayered Shields

10.6 Nuclear Reactor Shielding: Principles of Reactor Shielding

10.7 Removal Cross Sections

10.8 Reactor Shield Design: Removal—Attenuation Calculations

10.9 The Removal—Diffusion Method

10.10 Exact Methods

10.11 Shielding y-Rays

10.12 Coolant Activation

10.13 Ducts in Shields




11. Reactor Licensing, Safety, and the Environment

11.1 Governmental Authority and Responsibility

11.2 Reactor Licensing

11.3 Principles of Nuclear Power Plant Safety

11.4 Dispersion of Effluents from Nuclear Facilities

11.5 Radiation Doses from Nuclear Plants

11.6 Reactor Siting

11.7 Reactor Accidents

11.8 Accident Risk Analysis

11.9 Environmental Radiation Doses





I. Units and Conversion Factors 743

II. Fundamental Constants and Data 749

III. Vector Operations in Orthogonal Curvilinear Coordinates 759

IV. Thermodynamic and Physical Properties 765

V. Bessel Functions