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Library | Item Barcode | Call Number | Material Type | Item Category 1 | Status |
|---|---|---|---|---|---|
Searching... | 30000010120779 | QC23.2 Y683 2007 | Open Access Book | Book | Searching... |
Searching... | 30000010106757 | QC23.2 Y68 2007 | Open Access Book | Book | Searching... |
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Summary
Summary
KEY BENEFIT: For more than five decades, Sears and Zemansky's College Physics has provided the most reliable foundation of physics education for readers around the world. For the Eighth Edition, Robert Geller joins Hugh Young to produce a comprehensive update of this benchmark text. A broad and thorough introduction to physics, this new edition carefully integrates many solutions from educational research to help readers to develop greater confidence in solving problems, deeper conceptual understanding, and stronger quantitative-reasoning skills, while helping them connect what they learn with their other courses and the changing world around them. KEY TOPICS: Models, Measurements, and Vectors, Motion along a Straight Line, Motion in a Plane, Newton's Laws of Motion, Applications of Newton's Laws, Circular Motion and Gravitation, Work and Energy, Momentum, Rotational Motion, Dynamics of Rotational Motion, Elasticity and Periodic Motion, Mechanical Waves and Sound, Fluid Mechanics, Temperature and Heat, Thermal Properties of Matter, The Second Law of Thermodynamics, Electric Charges, Forces and Fields, Electric Potential and Electric Energy, Electric Current and Direct-Current Circuits, Magnetism, Magnetic Flux and Faraday's Law of Induction, Alternating Currents, Electromagnetic Waves, Geometric Optics, Optical Instruments, Interference and Diffraction, Relativity, Photons, Electrons, and Atoms, Atoms, Molecules, and Solids, 30 Nuclear and High-Energy Physics For all readers interested in most reliable foundation of physics education.
Author Notes
Hugh D. Young is Professor of Physics at Carnegie Mellon University in Pittsburgh, PA. He attended Carnegie Mellon for both undergraduate and graduate study and earned his Ph.D. in fundamental particle theory under the direction of the late Richard Cutkosky. He joined the faculty of Carnegie Mellon in 1956, and has also spent two years as a visiting Professor at the University of California at Berkeley. Hugh's career has centered entirely around undergraduate education. He has written several undergraduate-level textbooks, and in 1973 he became a coauthor with Francis Sears and Mark Zemansky for their well-known introductory texts. In addition to his role on Sears and Zemansky's College Physics , he is currently a coauthor with Roger Freedman on Sears and Zemanksy's University Physics .
Hugh is an enthusiastic skier, climber, and hiker. He also served for several years as Associate Organist at St. Paul's Cathedral in Pittsburgh, and has played numerous organ recitals in the Pittsburgh area. Prof. Young and his wife Alice usually travel extensively in the summer, especially in Europe and in the desert canyon country of southern Utah.
Robert M. Geller teaches physics at the University of California, Santa Barbara, where he also obtained his Ph.D. under Robert Antonucci in observational cosmology. Currently, he is involved in two major research projects: a search for cosmological halos predicted by the Big Bang, and a search for the flares that are predicted to occur when a supermassive black hole consumes a star.
Rob also has a strong focus on undergraduate education. In 2003, he received the Distinguished Teaching Award. He trains the graduate student teaching assistants on methods of physics education. He is also a frequent faculty leader for the UCSB Physics Circus, in which student volunteers perform exciting and thought-provoking physics demonstrations to elementary schools.
Rob loves the outdoors. He and his wife Susanne enjoy backpacking along rivers and fly fishing, usually with rods she has build and flies she has tied. Their daughter Zoe loves fishing too, but her fish tend to be plastic, and float in the bathtub.
Table of Contents
| Chapter 1 Physics of a CD player | p. 2 |
| BIO: Echolocation in bats | p. 3 |
| Train crash illustrates the importance of precision in measurement | p. 10 |
| Vectors in a caribou's swim across a river | p. 14 |
| Chapter 2 Average velocity on "the crookedest street in the world" | p. 32 |
| Average speed/average velocity of a race car | p. 37 |
| Negative acceleration of a drag racer | p. 39 |
| BIO: Human centrifuge | p. 42 |
| Chapter 3 High-performance yo-yos | p. 69 |
| A car's three accelerators | p. 72 |
| Rate of change of velocity in juggling | p. 77 |
| BIO: Bombardier beetle demonstrating projectile motion | p. 79 |
| Human cannonball as projectile | p. 82 |
| Uniform circular motion in global positioning systems | p. 87 |
| Chapter 4 Catapult demonstrating Newton's first law | p. 102 |
| Tablecloth trick: Inertia | p. 103 |
| Bubble chamber image: Studying particles | p. 107 |
| Lunar golf | p. 111 |
| Biathlete using Newton's third law | p. 113 |
| Rocket launch | p. 115 |
| Tug-of-war | p. 116 |
| Chapter 5 Crane unloading Very Large Telescope mirror | p. 129 |
| Liquid-filled accelerometer | p. 134 |
| Rock climber using frictional forces | p. 138 |
| Wet saw cutting stone | p. 139 |
| Chapter 6 BIO: Ultracentrifuge | p. 162 |
| Centripetal force in bobsledding | p. 163 |
| BIO: Runner using Newton's third law | p. 170 |
| Gravity map of the earth | p. 173 |
| "Skycycle" takeoff | p. 176 |
| Chapter 7 BIO: Elastic potential energy in kangaroo hopping | p. 191 |
| Reduced air drag on a recumbent bicycle | p. 193 |
| BIO: Elasticity of tendons and ligaments | p. 201 |
| BIO: Carrying weight on the head | p. 203 |
| BIO: Energy expended in climbing El Capitan | p. 207 |
| BIO: Grasshopper's catapult mechanism | p. 208 |
| BIO: Measuring a llama's oxygen consumption | p. 216 |
| Chapter 8 BIO: Contrecoup brain injury | p. 232 |
| Conservation of momentum in a bowling strike | p. 235 |
| Momentum of sumo wrestlers | p. 241 |
| Light sail | p. 244 |
| BIO: Frog's legs demonstrating impulse | p. 248 |
| Center of mass in balancing acrobats | p. 253 |
| BIO: Jet propulsion in jellyfish | p. 255 |
| Chapter 9 Hand drill demonstrating angular velocity | p. 269 |
| Velocipede direct-drive bicycle | p. 274 |
| Storing energy in a flywheel | p. 277 |
| Moon orbiting earth | p. 282 |
| Chapter 10 Balancing on a tightrope | p. 297 |
| Oxen turning water-well lift | p. 304 |
| Nanoengineered gears | p. 306 |
| Andaman earthquake's effects on length of day | p. 308 |
| Spinning dinner plates | p. 313 |
| Rifling in a gun barrel | p. 318 |
| Chapter 11 Cable-stayed bridge | p. 335 |
| Weighing a fish | p. 336 |
| Bio: Buoyancy in deep-sea hatchetfish | p. 337 |
| Bio: Strength and elasticity in a spider's web | p. 340 |
| Nanobalance | p. 348 |
| Foucault pendulum | p. 353 |
| Bio: Injuries from a jackhammer's vibrations | p. 354 |
| Chapter 12 Earthquakes: Transverse and longitudinal waves | p. 367 |
| Wave generation in a surf pool | p. 368 |
| Superposition of mechanical waves in water ripples | p. 375 |
| Bone flutes: Standing waves | p. 384 |
| Bio: Sound-wave vibrations in the human ear | p. 386 |
| Use of sonar in search of shipwrecks | p. 391 |
| Doppler radar in meteorology | p. 395 |
| Chapter 13 Differing liquid densities in a coffee drink | p. 408 |
| Bio: Measuring fluid pressure in the human eyeball | p. 412 |
| Snowshoeing to reduce pressure | p. 413 |
| Bio: Floating in the Dead Sea | p. 418 |
| Turbulent flow in a meandering river | p. 424 |
| Roof blown off by hurricane | p. 425 |
| Chapter 14 Hydrothermal vent | p. 444 |
| Bimetallic strip | p. 447 |
| Snowflakes | p. 455 |
| Bio: Using a calorimeter to measure a cow's heat production | p. 458 |
| Bio: Heat conduction in predatory fishes | p. 461 |
| Hawaiian islands: Built by convective flow | p. 465 |
| Bio: Infared images | p. 466 |
| Solar car | p. 467 |
| Chapter 15 The Milky Way: One trillionth of a mole of stars | p. 478 |
| Martian dust devil | p. 480 |
| Bio: Scuba-diving hazards | p. 483 |
| High-temperature calibration of a platinum resistance thermometer | p. 485 |
| Hydrogen affects planet size | p. 489 |
| Venus: An arid furnace | p. 490 |
| Nuclear submarines as steamships | p. 495 |
| Chapter 16 The sun's energy | p. 517 |
| Geothermal power in Iceland | p. 518 |
| "Bio-diesel" engines | p. 522 |
| How a refrigerator works | p. 523 |
| Energy cycles of the earth and its organisms | p. 535 |
| Zero-power homes | p. 536 |
| Chapter 17 Electric charge preceding a lightning strike | p. 546 |
| Salt water conducts electricity | p. 549 |
| Bio: "Static cling" in DNA | p. 552 |
| Atom-smashing with Van de Graaff generators | p. 553 |
| Bio: Platypus sensing electric fields | p. 558 |
| Bio: Fish producing and using an electric field to sense its surroundings | p. 565 |
| Car acting as a Faraday cage in an electrical storm | p. 572 |
| Chapter 18 Bio: Voltage-gated potassium channel in cell membrane | p. 583 |
| Lightning bolt | p. 587 |
| Bio: Bird perching on power line | p. 589 |
| Sandia Lab's capacitor bank discharging | p. 596 |
| Bio: Capacitors in cardiac defibrillators | p. 604 |
| Chapter 19 Semiconductors | p. 619 |
| Magnetic-levitation trains | p. 622 |
| Bio: Electric eels | p. 625 |
| Bio: Recharging ATP molecules | p. 630 |
| LED bicycle lights | p. 631 |
| Bio: Wrist strap grounding electronics worker | p. 643 |
| Chapter 20 Bio: Homing pigeons: Using earth's magnetic field | p. 661 |
| Bio: Magnetic resonance imaging | p. 664 |
| Microwave ovens | p. 667 |
| Direct-current motors | p. 673 |
| Coaxial cable | p. 677 |
| Magnetohydrodynamic pump | p. 683 |
| Chapter 21 Induction cooktop | p. 699 |
| Portable energy pack | p. 705 |
| Using an electromagnetic tether to deorbit satellites | p. 710 |
| Recharging pad for electronic devices | p. 712 |
| Using magnetic fields to catch red-light runners | p. 716 |
| Step-down transformers | p. 717 |
| L-C circuits in tuning knobs | p. 725 |
| Chapter 22 Alternating and direct current | p. 738 |
| Power surge protection | p. 749 |
| Chapter 23 Radio antenna | p. 762 |
| Cerenkov radiation in a nuclear reactor pool | p. 763 |
| Galaxy in different spectral regions | p. 765 |
| Bio: Ultraviolet vision in animals | p. 765 |
| Physics of a double rainbow | p. 783 |
| Photoelastic stress analysis | p. 789 |
| Chapter 24 Driver's blind spot | p. 804 |
| Side-view convex mirrors | p. 811 |
| Bio: Seeing in focus | p. 816 |
| Diamond lenses used in optical data storage | p. 821 |
| Chapter 25 Bio: Compound eyes | p. 841 |
| Bio: Animals' focusing mechanisms | p. 842 |
| Eyeglass lenses | p. 843 |
| X-ray telescope | p. 850 |
| Telescope mirrors | p. 852 |
| Chapter 26 Waves diffracting in the ocean | p. 863 |
| Nonreflective coating on museum cases | p. 872 |
| Bio: Structural color in butterflies | p. 873 |
| Bio: Using diffraction gratings to measure DNA | p. 880 |
| Reflection diffraction grating in CDs | p. 880 |
| Modern telescopes using interferometry | p. 888 |
| Chapter 27 Throwing a ball: Inertial frame of reference | p. 901 |
| Time at the finish line | p. 906 |
| Time travel | p. 909 |
| Space and time | p. 914 |
| Nuclear power: E = mc[superscript 2] | p. 920 |
| Chapter 28 Smoke detectors | p. 934 |
| Fireworks | p. 941 |
| Ruby lasers | p. 951 |
| Bio: Boron neutron capture therapy for brain cancer | p. 956 |
| Bio: Electron microscopy | p. 961 |
| Chapter 29 "Neon" lights | p. 980 |
| Bio: DNA double helix: Bonding | p. 984 |
| Diamonds and graphite | p. 990 |
| Electron vacancies in semiconductors | p. 993 |
| Transistor radio | p. 996 |
| Chapter 30 Size of nucleus relative to atom | p. 1004 |
| Bio: Penetrating power of different types of radiation | p. 1012 |
| Bio: Radiocarbon dating | p. 1017 |
| Bio: Residence time of radionuclides in the body | p. 1019 |
| Bio: Gamma-ray radiosurgery | p. 1020 |
| Bio: Nuclear medicine: Bone scans | p. 1021 |
