Quantum Physics for Scientists and Technologists Fundamental Principles and Applications for Biologists, Chemists, Computer Scientists, and Nanotechnologists
, by Sanghera, Paul
- ISBN: 9780470294529 | 0470294523
- Cover: Hardcover
- Copyright: 4/12/2011
Presenting quantum physics for the non-physicists, Quantum Physics for Scientists and Technologists is a self-contained, cohesive, concise, yet comprehensive, story of quantum physics from the fields of science and technology, including computer science, biology, chemistry, and nanotechnology. The authors explain the concepts and phenomena in a practical fashion with only a minimum amount of math. Examples from, and references to, computer science, biology, chemistry, and nanotechnology throughout the book make the material accessible to biologists, chemists, computer scientists, and non-technologists.
Shows how quantum mechanics explains the periodic table of elements Paul Sanghera, PhD, is an educator, scientist, technologist, and entrepreneur. He has worked at world-class laboratories such as CERN in Europe and Nuclear Lab at Cornell, where he participated in designing and conducting experiments to test the quantum theories and models of subatomic particles. Dr. Sanghera is the author of several bestselling books in the fields of science, technology, and project management as well as the author/coauthor of more than 100 research papers on the subatomic particles of matter published in reputed European and American research journals.
| Acknowledgments | p. xv |
| About the Author | p. xvii |
| About the Tech Editor | p. xix |
| Periodic Table of the Elements | p. xxi |
| Fundamental Physical Constants | p. xxiii |
| Important Combinations of Physical Constants | p. xxv |
| Preface: Science, Technology, and Quantum Physics: Mind the Gap | p. xxvii |
| First, There Was Classical Physics | p. 1 |
| Introduction | p. 2 |
| Physics and Classical Physics | p. 3 |
| The Classical World of Particles | p. 10 |
| Physical Quantities | p. 12 |
| Newton's Laws of Motion | p. 15 |
| Rotational Motion | p. 18 |
| Superposition and Collision of Particles | p. 22 |
| Superposition | p. 22 |
| Collision and Scattering | p. 25 |
| Classical World of Waves | p. 26 |
| Periodic Waves | p. 27 |
| Defining Wave Characteristics | p. 27 |
| Reflection, Refraction, and Scattering | p. 30 |
| Diffraction and Interference | p. 32 |
| Diffraction | p. 32 |
| Interference | p. 34 |
| Equation of Wave Motion | p. 35 |
| Light: Particle or Wave? | p. 38 |
| Understanding Electricity | p. 39 |
| Understanding Magnetism | p. 45 |
| Magnetic Field | p. 45 |
| Magnetic Flux | p. 47 |
| Understanding Electromagnetism | p. 49 |
| Types of Electromagnetic and Other Waves | p. 49 |
| Electromagnetic Spectrum | p. 50 |
| Maxwell's Equations | p. 52 |
| Confinement, Standing Waves, and Wavegroups | p. 55 |
| Confinement | p. 55 |
| Standing Waves | p. 55 |
| Wavegroups | p. 59 |
| Particles and Waves: The Big Picture | p. 62 |
| The Four Fundamental Forces of Nature | p. 63 |
| Gravitational Force | p. 65 |
| Electromagnetic Force | p. 66 |
| Weak and Strong Nuclear Forces | p. 67 |
| Four Fundamental Forces: The Big Picture | p. 68 |
| Unification: A Secret to Scientific and Technological Revolutions | p. 69 |
| Special Theory of Relativity | p. 72 |
| Classical Approach | p. 75 |
| Separation of Particles and Waves: Either It Is a Particle or a Wave | p. 75 |
| Either It Is Here or There: The Certainty | p. 75 |
| The World Is Continuous: Any Value Within a Range Is Possible | p. 76 |
| Common Grounds Among Particles and Waves: A Red Flag | p. 76 |
| Summary | p. 77 |
| Additional Problems | p. 78 |
| Particle Behavior of Waves | p. 80 |
| Introduction | p. 82 |
| The Nature of Light: The Big Picture | p. 82 |
| Black-Body Radiation | p. 84 |
| The Classical Collapse | p. 85 |
| The Quantum Rescue | p. 89 |
| The Photoelectric Effect | p. 93 |
| The Photoelectric Effect: The Experiment | p. 93 |
| The Classical Collapse | p. 95 |
| The Quantum Rescue | p. 98 |
| X-Ray Diffraction | p. 103 |
| The Compton Effect | p. 106 |
| Living in the Quantum World | p. 110 |
| Using Black-Body Radiation | p. 110 |
| Using the Photoelectric Effect | p. 111 |
| Using Compton Scattering | p. 113 |
| Summary | p. 114 |
| Additional Problems | p. 115 |
| Wave Behavior of Particles | p. 117 |
| Introduction | p. 118 |
| Particles and Waves: The Big Picture | p. 118 |
| The de Broglie Hypothesis | p. 120 |
| Measuring the Wavelength of Electrons | p. 125 |
| Quantum Confinement | p. 129 |
| The Uncertainty Principle | p. 133 |
| Understanding Particle Waves | p. 133 |
| Understanding the Uncertainty Principle | p. 136 |
| Another Form of the Uncertainty Principle | p. 140 |
| Wave-Particle Duality of Nature | p. 141 |
| Living in the Quantum World | p. 143 |
| Seeing the Nanoworld with Electron Waves | p. 143 |
| Seeing Nanostructures with the Diffraction of Particle Waves | p. 145 |
| Using Atomic Waves to Navigate Your Way | p. 147 |
| Summary | p. 147 |
| Additional Problems | p. 148 |
| Anatomy of an Atom | p. 150 |
| Introduction | p. 151 |
| Quantum Mechanics of an Atom: The Big Picture | p. 152 |
| Dalton's Atomic Theory | p. 153 |
| The Structure of an Atom | p. 154 |
| The Classical Collapse of an Atom | p. 157 |
| The Quantum Rescue | p. 161 |
| Bohr's Model | p. 161 |
| The Bohr Model Meets the Spectral Series | p. 165 |
| Limitations of the Bohr Model | p. 171 |
| Quantum Mechanics of an Atomic Structure | p. 171 |
| Principle Energy Levels | p. 172 |
| Sublevels | p. 173 |
| Electron Orbitals | p. 173 |
| Classical Physics or Quantum Physics: Which One Is the True Physics? | p. 175 |
| Living in the Quantum World | p. 178 |
| Free Electron Model for Pi Bonding | p. 178 |
| Summary | p. 180 |
| Additional Problems | p. 180 |
| Principles and Formalism of Quantum Mechanics | p. 182 |
| Introduction | p. 183 |
| Here Comes Quantum Mechanics | p. 184 |
| Wave Function: The Basic Building Block of Quantum Mechanics | p. 185 |
| It Is All about Information | p. 186 |
| Introducing Probability in Science | p. 186 |
| Operators: The Information Extractors | p. 189 |
| Predicting the Measurements | p. 189 |
| Expectation Values | p. 191 |
| Operators | p. 193 |
| Put It All into an Equation | p. 196 |
| Eigenfunctions and Eigenvalues | p. 198 |
| Double Slit Experiment Revisited | p. 200 |
| Double Slit Experiment for Particles | p. 201 |
| Chasing the Electron | p. 202 |
| The Quantum Reality | p. 204 |
| Living in the Quantum World | p. 206 |
| Summary | p. 208 |
| Additional Problems | p. 209 |
| The Anatomy and Physiology of an Equation | p. 210 |
| Introduction | p. 211 |
| The Schrödinger Wave Equation | p. 211 |
| The Schrödinger Equation for a Free Particle | p. 217 |
| Schrödinger Equal ion for a Particle in a Box | p. 219 |
| Setting Up and Solving the Schrödinger Equation | p. 220 |
| Here Comes the Energy Quantization | p. 221 |
| Exploring the Solutions of the Schrödinger Equation | p. 224 |
| The Uncertainty and Correspondence Principles: Revisited | p. 226 |
| Quantum Mechanical Tunneling | p. 228 |
| A Particle in a Three-Dimensional Box | p. 232 |
| Harmonic Oscillator | p. 234 |
| Understanding Harmonic Motion | p. 234 |
| Harmonic Motion in Quantum Mechanics | p. 238 |
| Understanding the Wave Functions of a Harmonic Oscillator | p. 243 |
| Comparing Quantum Mechanical Oscillator with Classical Oscillator | p. 247 |
| Living in the Quantum World | p. 250 |
| Summary | p. 252 |
| Additional Problems | p. 252 |
| Quantum Mechanics of an Atom | p. 254 |
| Introduction | p. 255 |
| Applying the Schrödinger Equation to the Hydrogen Atom | p. 257 |
| Solving the Schrödinger Equation for the Hydrogen Atom | p. 260 |
| Separating the Variables in the Schrödinger Equation | p. 260 |
| Solution of the Azimuthal Equation | p. 262 |
| Solutions of the Angular Equation | p. 264 |
| Solutions of the Radial Equation | p. 264 |
| Solutions of the Schrödinger Equation for the Hydrogen Atom: Putting It All Together | p. 267 |
| Finding the Electron | p. 270 |
| Understanding the Quantum Numbers | p. 273 |
| The Principal Quantum Number and Energy Radiations | p. 273 |
| The Orbital Quantum Number | p. 276 |
| Magnetic Quantum Number | p. 280 |
| The Significance of Hydrogen | p. 282 |
| Living in the Quantum World | p. 282 |
| Summary | p. 284 |
| Additional Problems | p. 286 |
| Quantum Mechanics of Many-Electron Atoms | p. 287 |
| Introduction | p. 288 |
| Two Challenges to Quantum Mechanics: The Periodic Table and the Zeeman Effect | p. 289 |
| The Periodic Table of Elements | p. 290 |
| The Split Spectral Lines and the Zeeman Effect | p. 291 |
| Introducing the Electron Spin | p. 292 |
| Exclusion Principle | p. 295 |
| Understanding the Atomic Structure | p. 298 |
| Understanding Shells, Subshells, and Orbitals | p. 298 |
| Understanding the Electron Configuration of Atoms | p. 301 |
| Understanding the Physical Basis of the Periodic Table | p. 307 |
| General Trends Across Groups and Periods | p. 310 |
| Alkalis and Alkaline Earths | p. 312 |
| Transition Metals | p. 312 |
| Inert Gases | p. 313 |
| Halogens | p. 313 |
| Lanthanides and Actinides | p. 314 |
| Completing the Story of Angular Momentum | p. 314 |
| Understanding the Zeeman Effect | p. 317 |
| Living in the Quantum World | p. 319 |
| Summary | p. 321 |
| Additional Problems | p. 322 |
| Quantum Mechanics of Molecules | p. 324 |
| Introduction | p. 325 |
| A System of Molecules in Motion | p. 327 |
| Bond: The Atomic Bond | p. 329 |
| Diatomic Molecules | p. 334 |
| Rotational States of Molecules | p. 336 |
| Vibrational States of Molecules | p. 340 |
| Combination of Rotations and Vibrations | p. 344 |
| Electronic States of Molecules | p. 350 |
| Living in the Quantum World | p. 351 |
| Summary | p. 353 |
| Additional Problems | p. 354 |
| Statistical Quantum Mechanics | p. 356 |
| Introduction | p. 357 |
| Statistical Distributions | p. 358 |
| Maxwell-Boltzmann Distribution | p. 360 |
| Molecular Systems with Quantum States | p. 369 |
| Distribution of Vibrational Energies | p. 371 |
| Vibrational Energy | p. 372 |
| Population Probability of Vibrational States | p. 373 |
| Correspondence with Classical Mechanics | p. 376 |
| Distribution of Rotational Energies | p. 378 |
| Rotational Energy | p. 378 |
| Population Probability of Rotational States | p. 378 |
| Correspondence with Classical Mechanics | p. 380 |
| Distribution of Translational Energies | p. 381 |
| Quantum Statistics of Distinguishable Particles: Putting It Together | p. 384 |
| Quantum Statistics of Indistinguishable Particles | p. 386 |
| Planck's Radiation Formula | p. 391 |
| Absorption, Emission, and Lasers | p. 394 |
| Bose-Einstein Condensation | p. 396 |
| Living in the Quantum World | p. 399 |
| Summary | p. 400 |
| Additional Problems | p. 402 |
| Quantum Mechanics: A Thread Runs through It all | p. 405 |
| Introduction | p. 406 |
| Nanoscience and Nanotechnology | p. 407 |
| Sciences behind Nanoscience | p. 407 |
| You Need to See Them before You Could Control Them | p. 410 |
| Nanoscale Quantum Confinement of Matter | p. 415 |
| Buckyballs | p. 415 |
| Carbon Nanotubes | p. 419 |
| Nanocrystals | p. 420 |
| Quantum Dots | p. 421 |
| Quantum Mechanics for Nanostructures | p. 423 |
| Favoring Balls and Tubes | p. 425 |
| Fruits of Quantum Confinement | p. 425 |
| Quick Overview of Microelectronics | p. 426 |
| Microelectronics: A Hindsight | p. 426 |
| Basics of Microchips | p. 428 |
| Quantum Computing | p. 432 |
| Quantum Biology | p. 434 |
| Four Fundamental Nanostructures of Life | p. 435 |
| Central Dogma of Molecular Biology | p. 441 |
| Sizes of Biological Particles | p. 442 |
| Diving Deeper into the Cell with Quantum Mechanics | p. 444 |
| Exploring the Interface of classical Mechanics and Quantum Mechanics | p. 449 |
| Living in the Quantum World | p. 449 |
| Summary | p. 451 |
| Additional Problems | p. 451 |
| Bibliography | p. 453 |
| Index | p. 455 |
| Table of Contents provided by Ingram. All Rights Reserved. |
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