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Take-Home Physics: 65 High-Impact, Low-Cost Labs


By: Michael Horton
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Details

Type of Product:NSTA Press Book (also see downloadable PDF version of this book)
Publication Date:5/30/2009
Pages:295
Stock Number:PB240X
ISBN:978-1-935155-05-8
Grade Level:High School
Read Inside:Read a sample chapter: Bernoulli’s Principle
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Our reviewers—top-flight teachers and other outstanding science educators—have determined that this resource is among the best available supplements for science teaching.
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Description

Take-Home Physics is an excellent resource for high school physics teachers who want to devote more classroom time to complex concepts while challenging their students with hands-on homework assignments. This volume presents 65 take-home physics labs that use ordinary household items or other inexpensive materials to tackle motion and kinematics; forces and energy; waves, sound, and light; and electricity and magnetism. The result: Students learn background knowledge, reinforce basic process skills, practice discovery, and bridge classroom learning with real-world application—all while getting excited about homework. Teachers can also integrate science and literacy by requiring the use of lab notebooks with formal write-ups. Materials lists and safety notes, as well as both student activity pages and teacher notes are included.


Ideas For Use

Additional Info

Science Discipline: (mouse over for full classification)
Batteries
Electromagnetism
Conservation of energy
Energy transfer
Thermodynamics
Acceleration
Electrical forces
Gravity
Inertia
Magnetism
Mass
Momentum
Newton’s laws of motion
Speed
Velocity
Absorption
Mirrors
Reflection
Refraction
Measuring
Scientific habits of mind
Sound
Intended User Role:Curriculum Supervisor, High-School Educator, Learner, Teacher
Educational Issues:Assessment of students, Classroom management, Curriculum, Inquiry learning, Instructional materials, Teacher preparation, Teaching strategies

Contents

Introduction

Why Take-Home Labs?

Evidence of Success

Inquiry in Physics

Teacher Feedback

Assembling the Materials

Master Materials List

Managing the Boxes

Safety

Section 1: Motion and Kinematics

Lab 1: Distance Versus Time Graphs 1

Lab 2: Distance Versus Time Graphs 2

Lab 3: Average Speed

Lab 4: Final Speed

Lab 5: Acceleration of Gravity 1

Lab 6: Acceleration of Gravity 2

Lab 7: Reaction Time

Lab 8: Terminal Velocity

Lab 9: Efficiency

Lab 10: Acceleration and Mass

Lab 11: Inertia

Lab 12: Conservation of Momentum 1

Lab 13: Conservation of Momentum 2

Lab 14: Newton’s Cradle

Lab 15: Independence of Velocity

Lab 16: Torque and First-Class Levers

Lab 17: What Is a Radian?

Lab 18: Circular Motion

Lab 19: Tangential Speed

Lab 20: Moment of Inertia

Lab 21: Elliptical Orbits

Lab 22: Hydrodynamics

Section 2: Forces and Energy

Lab 23: Unbalanced Forces

Lab 24: Center of Mass 1

Lab 25: Center of Mass 2

Lab 26: Center of Mass 3

Lab 27: Spring Constants

Lab 28: Spring Combinations

Lab 29: Centripetal Force

Lab 30: Conservation of Energy

Lab 31: Conversion of Energy

Lab 32: Bernoulli’s Principle

Lab 33: Buoyancy 1

Lab 34: Buoyancy 2

Lab 35: Buoyancy 3

Lab 36: Hero’s Engine

Lab 37: Pressure

Lab 38: Pressure Versus Depth

Lab 39: Thermodynamics

Section 3: Waves, Sound, and Light

Lab 40: Center of Percussion

Lab 41: Sound Waves

Lab 42: Refraction of Sound

Lab 43: Balloons and Ray Diagrams

Lab 44: Lenses and Ray Diagrams

Lab 45: Curved Mirrors

Lab 46: Color Addition

Lab 47: Diameter of the Sun

Lab 48: Intensity Versus Distance

Lab 49: Ripple Tank

Lab 50: Oil Spot Photometer

Lab 51: Waves and Interference

Section 4: Electricity and Magnetism

Lab 52: Creating Static Electricity

Lab 53: Attraction and Repulsion

Lab 54: Spark Length

Lab 55: Static Swing

Lab 56: Electricity and Safety

Lab 57: Battery and Lightbulb

Lab 58: Battery and LED

Lab 59: The Electrical Switch

Lab 60: Electromagnets

Lab 61: Magnetic Field Lines

Lab 62: Resistivity Equation

Lab 63: Series Resistors

Lab 64: Parallel Resistors

Lab 65: Series/Parallel Batteries

Index


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National Standards Correlation

This resource has 30 correlations with the National Standards.  
[VIEW CORRELATIONS]

This resource has 30 correlations with the National Standards.  
[HIDE CORRELATIONS]

  • Physical Science
    • Position and motion of objects
      • An object's motion can be described by tracing and measuring its position over time. (velocity) (K-4)
      • Sound is produced by vibrating objects. (K-4)
    • Light, heat, electricity, and magnetism
      • Light can be reflected by a mirror, refracted by a lens, or absorbed by the object. (K-4)
    • Transfer of Energy
      • Energy is a property of many substances and is associated with heat, light, electricity, mechanical motion, sound, nuclei, and the nature of a chemical. (5-8)
      • Energy is transferred in many ways. (5-8)
      • Light interacts with matter by transmission (including refraction), absorption, or scattering (including reflection). To see an object, light from that object—emitted by or scattered from it—must enter the eye. (5-8) (5-8)
      • To see an object, light from that object--emitted by or scattered from it--must enter the eye.
      • The sun's energy arrives as light with a range of wavelengths, consisting of visible light, infrared, and ultraviolet radiation. (5-8)
    • Motion and Forces
      • Objects change their motion only when a net force is applied. Laws of motion are used to calculate precisely the effects of forces on the motion of objects. (9-12)
      • The magnitude of the change in motion can be calculated using the relationship F = ma, which is independent of the nature of the force. (9-12)
      • Whenever one object exerts force on another, a force equal in magnitude and opposite in direction is exerted on the first object. (9-12)
      • Gravitation is a universal force that each mass exerts on any other mass. (9-12)
      • The strength of the gravitational attractive force between two masses is proportional to the masses and inversely proportional to the square of the distance between them. (9-12)
      • The electric force is a universal force that exists between any two charged objects. (9-12)
      • Opposite charges attract while like charges repel. (9-12)
      • The strength of the force is proportional to the charges and, as with gravitation, inversely proportional to the square of the distance between them. (9-12)
      • Electricity and magnetism are two aspects of a single electromagnetic force. (9-12)
      • Moving electric charges produce magnetic forces, and moving magnets produce electric forces. (9-12)
      • Unbalanced forces will cause changes in the speed or direction of an object's motion. (Acceleration) (5-8)
      • The motion of an object can be described by its position, direction of motion, and speed. (5-8)
      • An object that is not being subjected to a force will continue to move at a constant speed and in a straight line. (inertia) (5-8)
      • If more than one force acts on an object along a straight line, then the forces will reinforce or cancel one another, depending on their direction and magnitude. (5-8)
    • Interactions of energy and matter
      • Waves, including sound and seismic waves, waves on water, and light waves, have energy and can transfer energy when they interact with matter. (9-12)
      • Electromagnetic waves result when a charged object is accelerated or decelerated. (9-12)
      • Electromagnetic waves include radio waves (the longest wavelength), microwaves, infrared radiation (radiant heat), visible light, ultraviolet radiation, x-rays, and gamma rays. (9-12)
      • The energy of electromagnetic waves is carried in packets whose magnitude is inversely proportional to the wavelength. (9-12)
  • Science as Inquiry
    • Abilities necessary to do scientific inquiry
      • Think critically and logically to make the relationships between evidence and explanations.
    • Understandings about scientific inquiry
      • In presenting data, graphs are used to convey comparisons or trends. (9-12)
  • Teaching Standards
    • Teachers provide students with the time, space, and resources needed to learn science.
      • Create a setting for student work that is flexible and supportive of science inquiry.
      • Make the available science tools, materials, media, and technological resources accessible to students.


Published Reviews

“Michael Horton’s Take-Home Physics has many fine qualities. The introductory instructions are particularly valuable and benefit both novice and experienced teachers. Horton’s use of level-2 inquiry is entirely appropriate. …The book has an impressive array of activities to support any physics curriculum. Many of the experiments presented use simple, creative ways to explore fundamental physics concepts and provide enough evidence to reach valid conclusions.”
SB&F, January 2010


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