Physics for the Life Sciences 2nd Edition Zinke Solutions Manual
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Physics for the Life Sciences 2nd Edition Zinke Solutions Manual.
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Physics for the Life Sciences 2nd Edition Zinke Solutions Manual
Product Details:
- ISBN-10 : 0176502688
- ISBN-13 : 978-0176502683
- Author: Martin Zinke-Allmang (Author)
Taking an algebra-based approach with the selective use of calculus, this title includes basic physics concepts such as: using a fresh layout, consistent and student-tested art program, extensive use of conceptual examples, analytical problems, and instructive and engaging case studies.
Table of contents:
| PART 1: The Mechanics of Biological Systems | p. 1 |
| CHAPTER 1: Physics and the Life Sciences | p. 3 |
| The Predictable Universe | p. 3 |
| Significant Figures | p. 4 |
| Scientific Notation | p. 5 |
| Units of Measure | p. 8 |
| Dimensional Analysis | p. 11 |
| Proportionality | p. 12 |
| Order of Magnitude Estimation | p. 16 |
| CHAPTER 2: Kinematics | p. 22 |
| Measuring Motion | p. 22 |
| Distance and Displacement | p. 23 |
| Speed and Velocity | p. 24 |
| Acceleration | p. 28 |
| Motion in Two Dimensions | p. 32 |
| Uniform Circular Motion | p. 36 |
| Physiological Detection of Velocity | p. 38 |
| Physiological Detection of Acceleration | p. 40 |
| CHAPTER 3: Forces | p. 48 |
| Muscles as an Origin of Forces | p. 48 |
| What is a Force? | p. 50 |
| Properties of a Force | p. 52 |
| Action of a Force | p. 52 |
| Measuring Forces | p. 54 |
| Categories of Forces | p. 54 |
| Fundamental Forces | p. 54 |
| Convenience Forces | p. 58 |
| Free Body Diagram | p. 64 |
| Equilibrium | p. 65 |
| Can Our Bodies Detect Forces? | p. 67 |
| CHAPTER 4: Newton’s Laws | p. 77 |
| Newton’s Laws of Motion | p. 77 |
| Free Body Diagram, Revisited | p. 78 |
| Newton’s First Law | p. 80 |
| Newton’s Second Law | p. 83 |
| Newton’s Third Law | p. 86 |
| Application of Newton’s Laws, Convenience Forces Revisited | p. 90 |
| Weight and Apparent Weight | p. 97 |
| Physiological Applications of Newton’s Laws | p. 98 |
| CHAPTER 5:Centre of Mass and Linear Momentum | p. 112 |
| Centre of Mass Definition | p. 112 |
| Motion of the Centre of Mass | p. 118 |
| Newton’s Third Law and Linear Momentum | p. 119 |
| Changes of Linear Momentum and Newton’s Second Law | p. 122 |
| CHAPTER 6: Torque and Equilibrium | p. 129 |
| Force and Extended Object | p. 130 |
| Torque | p. 133 |
| Mechanical Equilibrium for a Rigid Object | p. 138 |
| Classes of Levers and Physiological Applications | p. 141 |
| Since When Did Hominids Walk on Two Legs? | p. 147 |
| PART 2: Energy, Biochemistry, and Transport Phenomena | p. 159 |
| CHAPTER 7: Energy and Its Conservation | p. 161 |
| Observations of Work and Energy | p. 161 |
| Basic Concepts | p. 165 |
| Work for a Single Object | p. 166 |
| Energy | p. 171 |
| Is Mechanical Energy Conserved? | p. 175 |
| CHAPTER 8: Gases | p. 186 |
| The Basic Parameters of the Respiratory System at Rest | p. 187 |
| Pressure-Volume Relations of the Air in the Lungs | p. 192 |
| The Empirical Gas Laws | p. 194 |
| Mechanical Model of the Ideal Gas | p. 201 |
| Energy Contained in the Ideal Gas | p. 205 |
| Implications of the Kinetic Gas Theory | p. 206 |
| Mixed Gases | p. 207 |
| CHAPTER 9: Work and Heat for Non-Mechanical Systems | p. 217 |
| Quantitative Representation of Dynamic Breathing | p. 218 |
| Work on or by a Gas | p. 219 |
| Work for Systems with Variable Pressure | p. 220 |
| Heat and the First Law of Thermodynamics | p. 224 |
| The Physics of the Respiratory System | p. 228 |
| CHAPTER 10: Thermodynamics | p. 237 |
| Quantifying Metabolic Processes | p. 237 |
| Basic Thermodynamic Processes | p. 240 |
| Cyclic Processes | p. 246 |
| Reversibility | p. 249 |
| The Second Law of Thermodynamics | p. 251 |
| Chemical Thermodynamics: An Overview | p. 256 |
| Liquid Solutions: Raoult’s Law | p. 260 |
| CHAPTER 11: The Transport of Energy and Matter | p. 269 |
| Membranes in Living Organisms | p. 269 |
| A New Model System: Physical Membranes as an Idealised Concept | p. 270 |
| Heat Conduction | p. 272 |
| Diffusion | p. 281 |
| CHAPTER 12: Static Fluids | p. 294 |
| Model System: The Ideal Stationary Fluid | p. 295 |
| Pressure in an Ideal Stationary Fluid | p. 295 |
| Buoyancy | p. 300 |
| Fluid Surfaces | p. 306 |
| Bubbles and Droplets | p. 307 |
| Capillarity | p. 311 |
| CHAPTER 13: Fluid Flow | p. 320 |
| Basic Issues in Blood Flow | p. 320 |
| Flow of an Ideal Dynamic Fluid | p. 322 |
| Flow of a Newtonian Fluid | p. 330 |
| Special Topics in Fluid Flow | p. 339 |
| PART 3: Vibrations, Acoustics, and Hearing | p. 349 |
| CHAPTER 14: Elasticity and Vibrations | p. 350 |
| Elasticity | p. 352 |
| Plastic Deformations | p. 355 |
| Hooke’s Law | p. 358 |
| Vibrations | p. 359 |
| CHAPTER 15: Sound I | p. 372 |
| The Hearing of Dolphins | p. 372 |
| Piston-Confined Gas Under Hydraulic Stress | p. 375 |
| Waves in an Unconfined Medium | p. 377 |
| Waves in a Confined Medium | p. 387 |
| Resonance | p. 392 |
| Hearing | p. 394 |
| CHAPTER 16: Sound II | p. 402 |
| Sound Absorbtion | p. 402 |
| Reflection and Transmission of Waves at Flat Interfaces | p. 405 |
| The Ultrasound Image | p. 409 |
| Doppler Ultrasound: The Use of the Doppler Effect on Medicine | p. 413 |
| PART 4: Electric Phenomena | p. 419 |
| CHAPTER 17: Electric Force and Field | p. 420 |
| Electric Charge and Force | p. 422 |
| Newton’s Laws and Charged Objects | p. 425 |
| How Do We Approach Electric Phenomena in Life Science Applications? | p. 427 |
| Electric Field | p. 429 |
| CHAPTER 18: Electric Energy and Potential | p. 442 |
| Nerves as a Physical and Physiochemical System | p. 442 |
| The Electric Energy | p. 445 |
| The Electric Potential | p. 451 |
| Conservation of Energy | p. 454 |
| Capacitors | p. 455 |
| CHAPTER 19: The Flow of Charges | p. 466 |
| Moving Point Charges in a Resting Nerve | p. 467 |
| Electrochemistry of Resting Nerves | p. 472 |
| The Signal Decay Time of a Resting Nerve | p. 476 |
| Stimulated Nerve Impulses | p. 477 |
| Extended Case Study in Medicine: Electrocardiography | p. 485 |
| The Electrocardiogram | p. 488 |
| PART 5: Atomic, Electromagnetic, and Optical Phenomena | p. 497 |
| CHAPTER 20: The Atom | p. 498 |
| The Atom in Classical Physics: Rutherford’s Model | p. 499 |
| Semi-Classical Model: Niels Bohr’s Hydrogen Atom | p. 502 |
| Quantum Mechanical Model of the Atom | p. 507 |
| Appendix: Relatavistic Speed, Energy, and Momentum of an Electron | p. 514 |
| CHAPTER 21: Magnetism and Electromagnetic Waves | p. 520 |
| Magnetic Force and Field Due to an Electric Current | p. 521 |
| Magnetism Due to Charged Particles in Motion | p. 527 |
| Aston’s Mass Spectrometer | p. 530 |
| Interacting Electric and Magnetic Fields | p. 531 |
| Physics an Physiology of Colour | p. 539 |
| Chapter 22: Geometric Optics | p. 550 |
| What is Optics? | p. 551 |
| Reflection | p. 552 |
| Refraction | p. 558 |
| Applications of Optometry and Ophthalmology | p. 565 |
| The Light Microscope | p. 568 |
| CHAPTER 23: The Atomic Nucleus | p. 582 |
| Stable Atomic Nuclei | p. 583 |
| Nuclear Force and Energy | p. 585 |
| Radioactive Decay | p. 587 |
| Angular Momentum | p. 593 |
| Nuclear Spins in a Magnetic Field | p. 596 |
| Two-Level Systems | p. 600 |
| PART 6: Applied Clinical Physics | p. 607 |
| CHAPTER 24: X-Rays | p. 609 |
| Origin of X-Rays | p. 610 |
| Photon Interaction Processes with Matter | p. 615 |
| Photon Attenuation | p. 621 |
| Contrast in X-Ray Images | p. 626 |
| Radiation Dose | p. 626 |
| Appendix: Energy of Scattered Photon for the Compton Effect | p. 627 |
| CHAPTER 25: Diagnostic Nuclear Medicine | p. 631 |
| Historical Introduction | p. 631 |
| Radioactive Decay | p. 632 |
| The Detection of Radiation | p. 633 |
| The Gamma (Anger) Camera | p. 634 |
| Single-Photon Emission Computed Tomography (SPECT) Imaging | p. 635 |
| Positron Emission Tomnography (PET) Imaging | p. 637 |
| Clinical Applications | p. 639 |
| CHAPTER 26: Radiation Therapy | p. 642 |
| Introduction | p. 642 |
| The Co-60 Unit | p. 643 |
| The Medical Linear Accelerator | p. 645 |
| The Percent Depth Dose Function | p. 646 |
| The Tissue Air Ratio Function | p. 648 |
| Clinical Applications | p. 649 |
| CHAPTER 27: Nuclear Magnetic Resonance | p. 652 |
| Nuclear Magnetic Resonance in Organic Chemistry | p. 653 |
| Interactions of Nuclear Spins in Condensed Matter | p. 654 |
| Pulse Repetition Time and Time of Echo Spin Echo Technique | p. 657 |
| Imaging Utilising the Gradient Field Method | p. 661 |
| INDEX | p. 665 |
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