University Physics for the Physical and Life Sciences
Volume IFirst Edition| ©2012 Philip R. Kesten; David L. Tauck
Available for Fall 2012 classes.
Authors Philip R. Kesten and David L. Tauck take a fresh and innovative approach to the university physics (calculus-based) course. They combine their experience teaching physics (Kesten) and biology (Tauck) to create a text tha...
Available for Fall 2012 classes.
Authors Philip R. Kesten and David L. Tauck take a fresh and innovative approach to the university physics (calculus-based) course. They combine their experience teaching physics (Kesten) and biology (Tauck) to create a text that engages students by using biological and medical applications and examples to illustrate key concepts.
University Physics for the Physical and Life Sciences teaches the fundamentals of introductory physics, while weaving in formative physiology, biomedical, and life science topics to help students connect physics to living systems. The authors help life science and pre-med students develop a deeper appreciation for why physics is important to their future work and daily lives. With its thorough coverage of concepts and problem-solving strategies, University Physics for the Physical and Life Sciences can also be used as a novel approach to teaching physics to engineers and scientists or for a more rigorous approach to teaching the college physics (algebra-based) course.
• A seamless blend of physics and physiology with interesting examples of physics in students’ lives,
• A strong focus on developing problem-solving skills (Set Up, Solve, and Reflect problem-solving strategy),
• Conceptual questions (Got the Concept) built into the flow of the text,
• “Estimate It!” problems that allow students to practice important estimation skills
• Special attention to common misconceptions that often plague students, and
• Detailed artwork designed to promote visual learning
Volume I: 1-4292-0493-1
Volume II: 1-4292-8982-1
Institutional Prices
Available for Fall 2012 classes.
Authors Philip R. Kesten and David L. Tauck take a fresh and innovative approach to the university physics (calculus-based) course. They combine their experience teaching physics (Kesten) and biology (Tauck) to create a text that engages students by using biological and medical applications and examples to illustrate key concepts.
University Physics for the Physical and Life Sciences teaches the fundamentals of introductory physics, while weaving in formative physiology, biomedical, and life science topics to help students connect physics to living systems. The authors help life science and pre-med students develop a deeper appreciation for why physics is important to their future work and daily lives. With its thorough coverage of concepts and problem-solving strategies, University Physics for the Physical and Life Sciences can also be used as a novel approach to teaching physics to engineers and scientists or for a more rigorous approach to teaching the college physics (algebra-based) course.
• A seamless blend of physics and physiology with interesting examples of physics in students’ lives,
• A strong focus on developing problem-solving skills (Set Up, Solve, and Reflect problem-solving strategy),
• Conceptual questions (Got the Concept) built into the flow of the text,
• “Estimate It!” problems that allow students to practice important estimation skills
• Special attention to common misconceptions that often plague students, and
• Detailed artwork designed to promote visual learning
Volume I: 1-4292-0493-1
Volume II: 1-4292-8982-1
Features
Seamless integration of physics and physiology
Physiology and biomedical topics are woven throughout University Physics for the Physical and Life Sciences. The authors’ aim is to instill in students a deeper appreciation of physics by showing them how it determines many characteristics of living systems. Biological applications are called out in the table of contents and marked in the end of chapter problems. A biology appendix includes key biology topics referenced throughout the chapters’ biology margin notes.
A focus on developing problem-solving skills
Too many students would rather memorize equations than comprehend the underlying physics, a mistake that some textbooks encourage in the way they present material. This is compounded by the fact that students sometimes look for shortcuts in doing – and therefore learning – physics. This text models problem-solving skills by applying several common steps to all worked example problems. This procedure, summarized by the key phrases “Set Up,” “Solve,” and “Reflect,” mirrors the approach scientists take in attacking problems:
Set Up. The first step in each problem is to determine an overall approach and to gather together the necessary pieces of information needed to solve it. These might include sketches, equations related to the physics, and concepts.
Solve. Rather than simply summarizing the mathematical manipulations required to move from first principles to the final answer, Kesten and Tauck show many intermediate steps in working out solutions to the sample problems. Authors too often omit these intermediate steps, either as “an exercise for the student” or perhaps because they appear obvious. Students often do not find these missing steps obvious and, as a result, simply pass over what might otherwise be a valuable learning experience.
Reflect. An important part of the process of solving a problem is to reflect on the meaning, implications, and validity of the answer. Is it physically reasonable? Do the units make sense? Is there a deeper or wider understanding that can be drawn from the result? Kesten and Tauck take care to address these and related questions when appropriate.
Conceptual problems built into the flow of the text
Many calculus-based introductory physics texts include conceptual questions at the end of chapters, but few include them as part of the flow of the text. Health Science and biological sciences students, however, are used to a conceptual approach to both problem-solving and learning in general. In University Physics for the Physical and Life Sciences approximately one-third of all online problems in each chapter are conceptual. These Got the Concept? questions rarely require numeric calculations. Instead, students are encouraged to think through the implications or connections of a physics concept.
Estimation problems, in which students are asked to undertake “On the Napkin” calculations to better understand a given topic
Scientists often quickly estimate relationships and ideas by doing calculations on whatever scrap of paper is at hand – often a napkin or the back of an envelope. Computing a rough estimation can be a powerful tool in doing science, especially when just starting a new problem. The authors want to instill the use of estimations into students by modeling the behavior for them, and will encourage them to exploit the habit as they study physics and think about the world around them.
Special attention to common misconceptions that often plague students
Having taught physics and physiology for many years, both authors know which topics are often difficult for students. For example, physics students are often puzzled by a perception that mirrors reverse images horizontally but not vertically. Physiology students usually have a hard time grasping the idea that the velocity of blood flow is related to the total cross-sectional area of the vessels rather than the blood pressure. The authors hope that tackling these misconceptions directly through the Watch Out feature will draw the students into a deeper understanding of the physics as well as the physiology.
Detailed artwork designed to promote visual learning
In many textbooks figures contribute little to helping students learn the material. Kesten and Tauck use artwork as a teaching tool whenever possible, including as much information as is practical directly in the figures. The result is an annotated figure that reinforces the physics presented in the flow of the text. Moreover, the figures themselves are simple, colorful, and approachable, inviting students to explore them rather than intimidating students into ignoring them.
New to This Edition
“A refreshing way to talk about physics (from descriptive to cal-based, from serious PHYS to interesting facts of life science)."
— Chuji Wang, Mississippi State University“This is the best bio-app text I have seen.”
— Mark James, Northern Arizona University“The detailed development of biological examples sets the book apart.”
— Carey Witkov, Broward College“This [the Worked Example] is a nice introduction/review to basic calculus concepts. I appreciate it most when the author uses examples to reinforce the mathematics—not common in modern textbooks.”
— Mark Lattery, University of Wisconsin, Oshkosh“I think the estimations problems are a wonderful idea and I may start using them in my classes.”
— Robert Mania, Kentucky State University“I didn’t think of this book as physics with a life science bent. It is an Engineering physics book with plenty of applications in life science and other areas. It is appropriate for all engineers.”
“This calculus based book can be used for teaching students with no calculus background.”
— Bereket Berhane, Embry-Riddle Aeronautical University
— Prem Chapagain, Florida International University“I find this book easier to read than others, the language is more informal, yet it tells you everything.”
— Stiliana Savin, Barnard College
University Physics for the Physical and Life Sciences
First Edition| ©2012
Philip R. Kesten; David L. Tauck
University Physics for the Physical and Life Sciences
First Edition| 2012
Philip R. Kesten; David L. Tauck
Table of Contents
1 Physics: An Introduction
1. Speaking Physics
2. Physical Quantities and Units
3. Prefixes and Conversions
4. Significant Figures
5. Solving Problems
6. Dimensional Analysis
1. Constant Velocity Motion
2. Acceleration
3. Motion under Constant Acceleration
4. Gravity at the Surface of Earth
1. Horizontal and Vertical Motions are Independent
2. Vectors
3. Vector Components: Adding Vectors, Analyzing by Component
4. Projectile Motion
5. Uniform Circular Motion
1. Newton’s First Law
2. Newton’s Second Law
3. Mass and Weight
4. Free Body Diagrams
5. Newton’s Third Law
6. Force, Acceleration, Motion
1. Static Friction
2. Kinetic Friction
3. Working with Friction
4. Drag Force
5. Forces and Uniform Circular Motion
1. Work
2. The Work – Energy Theorem
3. Applications of the Work – Energy Theorem
4. Work Done by a Variable Force
5. Potential Energy
6. Conservation of Energy
7. Nonconservative Forces
8. Using Energy Conservation
7 Linear Momentum
1. Linear Momentum
2. Conservation of Momentum
3. Inelastic Collisions
4. Contact Time
5. Elastic Collisions
6. Center of Mass
8 Rotational Motion
1. Rotational Kinetic Energy
2. Moment of Inertia
3. The Parallel-Axis Theorem
4. Conservation of Energy Revisited
5. Rotational Kinematics
6. Torque
8. The Vector Nature of Rotational Quantities
9 Elasticity and Fracture
1. Tensile Stress and Strain
2. Volume Stress and Strain
3. Shear Stress and Strain
4. Elasticity and Fracture
1. Newton’s Universal Law of Gravitation
2. The Shell Theorem
3. Gravitational Potential Energy
4. Kepler’s Laws
11 Fluids
1. Density
2. Pressure
3. Pressure versus Depth in a Fluid
4. Atmospheric Pressure and Common Pressure Units
5. Pressure Difference and Net Force
6. Pascal’s Principle
7. Buoyancy – Archimedes’ Principle
8. Fluids in Motion and Equation of Continuity
9. Fluid Flow – Bernoulli’s Equation
10. Viscous Fluid Flow
1. Simple Harmonic Motion
2. Oscillations Described
3. Energy Considerations
4. The Simple Pendulum
5. Physical Oscillators
6. The Physical Pendulum
7. The Damped Oscillator
8. The Forced Oscillator
1. Types of Waves
2. Mathematical Description of a Wave
3. Wave Speed
4. Superposition and Interference
5. Transverse Standing Waves
6 Longitudinal Standing Waves
7. Beats
8. Volume, Intensity, and Sound Level
9. Moving Sources and Observers of Waves
1. Temperature
2. A Molecular View of Temperature
3. Mean Free Path
4. Thermal Expansion
5. Heat
6. Latent Heat
7. Heat Transfer: Radiation, Convection, Conduction
15 Thermodynamics II
1. The First Law of Thermodynamics
2. Thermodynamic Processes
3. The Second and Third Laws of Thermodynamics
4. Gases
5. Entropy
16 Electrostatics I
1. Electric Charge
2. Coulomb’s Law
3. Conductors and Insulators
4. Electric Field
5. Electric Field for some Objects
6. Gauss’s Law
7. Applications of Gauss’s Law
1. Electric Potential
2. Equipotential Surfaces
3. Electrical Potential due to Certain Charge Distributions
4. Capacitance
5. Energy Stored in a Capacitor
6. Capacitors in Series and Parallel
7. Dielectrics
1. Current
2. Resistance and Resistivity
3. Physical and Physiological Resistors
4. Direct Current Circuits
5. Resistors in Series and Parallel
6. Power
7. Series RC Circuits
8. Bioelectricity
19 Magnetism
1. Magnetic Force and Magnetic Field
2. Magnetic Force on a Current
3. Magnetic Field and Current –the Biot-Savart Law
4. Magnetic Field and Current–Ampère’s Law
5. Magnetic Force between Current-Carrying Wires
1. Faraday’s Law of Induction
2. Lenz’s Law
3. Applications of Faraday’s and Lenz’s Laws
4. Inductance
5. LC Circuits
6. LR Circuits
1. Alternating Current
2. Transformers
3. The Series LRC Circuit
4. L, R, C Separately With AC
5. L, R, C In Series With AC
6. Applications of a Series LRC Circuit
1. Electromagnetic Waves
2. Maxwell’s Equations
1. Refraction
2. Total Internal Reflection
3. Dispersion
4. Polarization
5. Thin Film Interference
6. Diffraction
7. Circular Apertures
1. Plane Mirrors
2. Spherical Concave Mirrors, a Qualitative Look
3. Spherical Concave Mirrors, a Quantitative Look
4. Spherical Convex Mirrors, a Qualitative Look
5. Spherical Convex Mirrors, a Quantitative Look
6. Lenses, a Qualitative Look
7. Lenses, a Quantitative Look
1. Newtonian Relativity
2. The Michelson and Morley Experiment
3, Special Relativity, Time Dilation
4. The Lorentz Transformation, Length Contraction
5. Lorentz Velocity Transformation
6. Relativistic Momentum and Energy
7. General Relativity
1. Blackbody Radiation
2. Photoelectric Effect
3. Compton Effect
4. Wave Nature of Particles
5. The Atom: Rutherford and Bohr
6. The Atom: Energy Levels and Spectra
1. The Nucleus
2. Binding Energy
3. Fission
4. Fusion
5. Nuclear radiation
1. The Standard Model: Particles
2. The Standard Model: Forces
3. Matter, Antimatter, Dark Matter
University Physics for the Physical and Life Sciences
First Edition| 2012
Philip R. Kesten; David L. Tauck
Authors
Philip R. Kesten
Dr. Philip Kesten, Associate Professor of Physics and Associate Provost for Residential Learning Communities at Santa Clara University, holds a B.S. in physics from the Massachusetts Institute of Technology and received his Ph.D. in high energy particle physics from the University of Michigan. Since joining the Santa Clara faculty in 1990, Dr. Kesten has also served as Chair of Physics, Faculty Director of the ATOM and da Vinci Residential Learning Communities, and Director of the Ricard Memorial Observatory. He has received awards for teaching excellence and curriculum innovation, was Santa Claras Faculty Development Professor for 2004-2005, and was named the California Professor of the Year in 2005 by the Carnegie Foundation for the Advancement of Education. Dr. Kesten is co-founder of Docutek, (A SirsiDynix Company), an Internet software company, and has served as the Senior Editor for Modern Dad, a newsstand magazine.
David L. Tauck
University Physics for the Physical and Life Sciences
First Edition| 2012
Philip R. Kesten; David L. Tauck
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University Physics for the Physical and Life Sciences
First Edition| 2012
Philip R. Kesten; David L. Tauck
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University Physics for the Physical and Life Sciences
First Edition| 2012
Philip R. Kesten; David L. Tauck
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