PHYS260
H2-52: BEATS AND RESONANCE - TUNING BARS
Category: H2 Wave Properties of Sound
Purpose:
To demonstrate beats, and to demonstrate resonance between two identical tuning bar resonators.
K8-42: RADIOWAVES - ENERGY AND DIPOLE PATTERN
Category: K8 Electromagnetic Waves and Sources
Purpose:
Demonstrates transmission of energy in electromagnetic waves. Shows the radiation pattern of the dipole antenna
M1-11 LASER DIFFRACTION - FIXED DOUBLE SLITS
Purpose:
Demonstrates double slit interference
M1-02 LASER DIFFRACTION - VARIABLE SINGLE SLIT
Purpose:
Demonstrates single slit diffraction
K8-45 RADIO WAVES FROM SPARK
Category: K8 Electromagnetic Waves and Sources
Purpose:
Demonstrates that a spark contains radio waves
K8-03 LIGHT NANOSECOND
Category: K8 Electromagnetic Waves and Sources
Purpose:
Shows the distance light travels in one nanosecond
K5-31 OHM'S LAW
Category: K5 Electrical Properties of Matter
Purpose:
Demonstrates relationship between current, voltage, and resistance
K5-12 BATTERY AND CURRENT - WORKING MODEL
Category: K5 Electrical Properties of Matter
Purpose:
Model of battery with circuit attached
K4-02 MAGNETOELECTRIC GENERATOR WITH LAMP
Category: K4 Motors and Generators
Purpose:
Demonstrates a small 110 VAC magnetoelectric generator
K1-14 OSCILLOSCOPE CRT - DEFLECTION BY MAGNET
Category: K1 Forces on Moving Particles
Purpose:
Demonstrates the force on an electron beam by a magnetic field
J5-20 OERSTED EXPERIMENT- LARGE COIL AND COMPASS
Category: J5 Magnetostatics
Purpose:
Demonstrates that magnetic fields are generated around current-carrying wires
J4-32 DISCHARGE OF CAPACITOR WITH BANG
Category: J4 Capacitance and Polarization
Purpose:
Demonstrates that capacitors store electrical energy
J4-31 ENERGY STORED IN A CAPACITOR
Category: J4 Capacitance and Polarization
Purpose:
Demonstrates that energy is stored in a capacitor and how that energy may be used
J4-22 PARALLEL PLATE CAPACITOR WITH DIELECTRIC
Category: J4 Capacitance and Polarization
Purpose:
Demonstrates that inserting a dielectric into a capacitor increases the capacitance
J4-04 PARALLEL PLATE CAPACITOR - IONIZATION OF AIR
Category: J4 Capacitance and Polarization
Purpose:
Demonstrates the mobility of ions
J4-01 PARALLEL PLATE CAPACITOR
Category: J4 Capacitance and Polarization
Purpose:
Demonstrates that potential difference across a capacitor is proportional to the plate separation
J3-24 HOLLOW CONDUCTING SPHERE
Category: J3 Electric Fields and Potential
Purpose:
Demonstrates that charge resides on the outside surface of a conductor
J3-23 FARADAY CAGE - RADIOWAVES
Category: J3 Electric Fields and Potential
Purpose:
Demonstrates that radio waves cannot penetrate a Faraday cage
J3-21 FARADAY CAGE
Category: J3 Electric Fields and Potential
Purpose:
Demonstrates that the electric field within a closed conducting surface is zero
J3-14 FLUX MODEL - ELECTROSTATICS
Category: J3 Electric Fields and Potential
Purpose:
Aid in visualizing flux at an angle through a surface
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I6-01 GAS PRESSURE - MODEL
Illustrates the molecular nature of gas pressure
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I6-02: NITROGEN DIAMETER AND MEAN FREE PATH
Experimentally determine the diameter of the nitrogen molecule and to determine the order of magnitude of the mean free path… Read More
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I6-03 EQUIPARTITION OF ENERGY
Demonstrates equipartition of energy
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I6-11: BROWNIAN MOTION WITH TV
Demonstrates equipartition of energy
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I6-13: AIR TABLE - MODEL OF BROWNIAN MOTION
Simple model of Brownian motion. Read More
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I6-21 GAS DIFFUSION - MODEL
Models gas diffusion through a small hole
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I6-22: IODINE DIFFUSION TUBES
Demonstrate diffusion. Read More
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I6-23 DIFFUSION - FOOD COLOR IN WATER
Demonstrates diffusion
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I6-24: DIFFUSION VELOCITY
Show that the diffusion velocity is proportional to the RMS molecular velocity. Read More
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I6-25: DIFFUSION - DISTRIBUTION OF PING PONG BALLS
Demonstrate on a macroscopic scale using ping pong balls how random molecular motion causes substances to diffuse. Read More
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I6-31: MOLECULAR MOTION DEMO - BROWNIAN MOTION
Model Brownian motion. Read More
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I6-32: MOLECULAR MOTION DEMO - RANDOM MOTION IN GASES
Model random molecular motion. Read More
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I6-33: MOLECULAR MOTION DEMO - GAS PRESSURE
Model gas pressure. Read More
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I6-34: MOLECULAR MOTION DEMO - TEMPERATURE OF A GAS
Model gas pressure. Read More
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I6-35: MOLECULAR MOTION DEMO - DIFFUSION
Model gas diffusion. Read More
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I6-36: MOLECULAR MOTION DEMO - AVOGADRO'S HYPOTHESIS
Help justify Avogadro's hypothesis using a model. Read More
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I6-37: MOLECULAR MOTION DEMO - VAN DER WALLS FORCES
Introduce the concept of attractive force between molecules. Read More
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I6-38: MOLECULAR MOTION DEMO - BOYLE'S LAW
Model Boyle's law. Read More
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I6-39: MOLECULAR MOTION DEMO - CHARLES' LAW
Model Charles' law. Read More
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I6-40: MOLECULAR MOTION DEMO - SOLIDS
Model the behavior of solids. Read More
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I6-41: MOLECULAR MOTION DEMO - LIQUIDS
Model the behavior of liquids. Read More
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I6-51 ENTROPY - SORTING MARBLES
Demonstrates that increasing entropy requires less energy than decreasing entropy
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I6-52: ENTROPY - FOUR BALLS IN GAS DIFFUSION MODEL
Demonstrate that an ordered state is statistically possible. Read More
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I6-61: MAXWELL'S DEMON
Example of a "Maxwell Demon." Read More
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