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I6-36: MOLECULAR MOTION DEMO - AVOGADRO'S HYPOTHESIS
Category:
I6 Kinetic Theory and Statistical Mechanics
Purpose
:
Help justify Avogadro's hypothesis using a model.
I6-35: MOLECULAR MOTION DEMO - DIFFUSION
Category:
I6 Kinetic Theory and Statistical Mechanics
Purpose
:
Model gas diffusion.
I6-34: MOLECULAR MOTION DEMO - TEMPERATURE OF A GAS
Category:
I6 Kinetic Theory and Statistical Mechanics
Purpose
:
Model gas pressure.
I6-33: MOLECULAR MOTION DEMO - GAS PRESSURE
Category:
I6 Kinetic Theory and Statistical Mechanics
Purpose
:
Model gas pressure.
I6-32: MOLECULAR MOTION DEMO - RANDOM MOTION IN GASES
Category:
I6 Kinetic Theory and Statistical Mechanics
Purpose
:
Model random molecular motion.
I6-31: MOLECULAR MOTION DEMO - BROWNIAN MOTION
Category:
I6 Kinetic Theory and Statistical Mechanics
Purpose
:
Model Brownian motion.
I6-25: DIFFUSION - DISTRIBUTION OF PING PONG BALLS
Category:
I6 Kinetic Theory and Statistical Mechanics
Purpose
:
Demonstrate on a macroscopic scale using ping pong balls how random molecular motion causes substances to diffuse.
I6-11: BROWNIAN MOTION WITH TV
Category:
I6 Kinetic Theory and Statistical Mechanics
Purpose
:
Demonstrate Brownian motion.
I5-03: MECHANICAL EQUIVALENT OF HEAT - JOULE'S METHOD
Category:
I5 Laws of Thermodynamics
Purpose
:
Determine the mechanical equivalent of heat.
I4-16: DRINKING BIRD
Category:
I4 Changes of State
Purpose
:
Stimulate thought about heat exchange and liquid-vapor phase transitions.
I4-14: CHANGE OF STATE WITH BANG
Category:
I4 Changes of State
Purpose
:
Demonstrate that the volume of a gas is much greater than the volume of the same amount of liquid.
I4-03: LATENT HEAT - ICE TO WATER TO STEAM
Category:
I4 Changes of State
Purpose
:
Show latent heat as ice is transformed to water and then to steam.
K7-45: LOW AND HIGH PASS FILTERS
Category:
K7 RLC Circuits
Purpose
:
Demonstrate use of a series RL circuit as a low-pass filter and a series RC circuit as a high-pass filter.
K7-41: RC CIRCUIT - DIFFERENTIATION AND INTEGRATION
Category:
K7 RLC Circuits
Purpose
:
Demonstrate differentiation and integration using RC circuits.
K7-29: RLC CIRCUIT - 0.6 HZ TRANSIENTS
Category:
K7 RLC Circuits
Purpose
:
Demonstrate transients using a circuit with a very long time constant.
K7-27: RLC CIRCUIT - COMPLETE
Category:
K7 RLC Circuits
Purpose
:
Show the phase shift between components in a series RLC circuit.
K7-26: RLC CIRCUIT - 0.3 HZ RESONANCE
Category:
K7 RLC Circuits
Purpose
:
Plot a graph of resonance behavior in a very low frequency resonant circuit.
K7-22: RLC CIRCUIT - 10 KHZ - DAMPED OSCILLATIONS
Category:
K7 RLC Circuits
Purpose
:
Demonstrate damped oscillations in an RLC circuit.
K7-21: RLC CIRCUIT - 10 KHZ - RESONANCE
Category:
K7 RLC Circuits
Purpose
:
Demonstrate resonance in an RLC circuit.
K7-14: RC CIRCUIT - 100 MICROSECOND TIME CONSTANT
Category:
K7 RLC Circuits
Purpose
:
Demonstrate a reasonably fast RC circuit.
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Page 2 of 20
A General Materials and Mathematics
A1 Basic Materials and Measurement
A2 Mathematics
B Statics
B1 Center of Mass Statics
B2 Equilibrium of Forces and Torques
B3 Simple Machines
B4 Elasticity
C Kinematics and Dynamics
C1 Center of Mass Motion
C2 Kinematics in One and Two Dimensions
C3 First Law of Motion
C4 Second Law of Motion
C5 Third Law of Motion
C6 Friction
C7 Collisions
C8 Mechanical Energy and Power
D Rotational Mechanics
D1 Rotational Kinematics and Dynamics
D2 Moment of Inertia
D3 Angular Momentum
D4 Gyroscopes
D5 Rotational Esoterica
E Gravitation and Astronomy
E1 Gravitation and Orbits
E2 Astronomy
F Fluid Mechanics
F1 Pressure in Static Fluids
F2 Buoyancy
F3 Surface Tension
F4 Fluid in Motion
F5 Forces in Moving Fluids
G Vibrations and Mechanical Waves
G1 Simple Harmonic Motion
G2 Resonance and Coupled Oscillations
G3 Mechanical Waves - One Dimensional
G4 Mechanical Waves - Two Dimensional
H Sound
H1 Nature of Sound
H2 Wave Properties of Sound
H3 Standing Sound Waves
H4 Music
H5 The Ear
H6 The Voice
I Thermodynamics
I1 Thermal Properties of Matter
I2 Transfer of Heat
I3 Gases
I4 Changes of State
I5 Laws of Thermodynamics
I6 Kinetic Theory and Statistical Mechanics
I7 Solid State and Low Temperature Physics
J Electostatics and Magnetostatics
J1 Electrostatic Charge and Force
J2 Electrostatic Devices and Applications
J3 Electric FIelds and Potential
J4 Capacitance and Polarization
J5 Magnetostatics
J6 Electromagnets
J7 Magnetic Materials
K Electromagnetic Principles
K1 Forces on Moving Charges
K2 Electromagnetic Induction
K3 Transformers
K4 Motors and Generators
K5 Electrical Properties of Matter
K6 Electric Circuits and Instruments
K7 RLC Circuits
K8 Electromagnetic Waves and Sources
L Geometrical Optics
L1 Light Sources and Light Rays
L2 Plane Mirrors
L3 Curved Mirrors
L4 Refraction
L5 Total Internal Reflection
L6 Lenses
L7 Optical Instruments
M Wave Optics
M1 Interference and Diffraction - Slits and Gratings
M2 Diffraction - Circular
M3 Interferometers
M4 Thin Film Interference
M5 Interference and Diffraction Esoterica
M6 Holograms
M7 Linear Polarization and Scattering
M8 Optical Activity and Birefringence
M9 Circular Polarization
N Spectra and Color
N1 Continuous Spectra
N2 Line Spectra
N3 Color
O Vision
O1 Image Production
O2 Visual Latency
O3 Color Vision
O4 Optical Illusions
P Modern Physics
P1 Relativity
P2 Quantum Mechanics
P3 Atoms and Molecules
P4 Nuclei and Particles
Q Biophysics
Q1 Musculoskeletal Systems
Q2 Organs
Q3 Genetics and Molecular Biology
F1-01 FLUID PRESSURE VS. DEPTH
Demonstrates that fluid pressure increases linearly with depth and is isotropic.
Read More
F1-02: FLUID PRESSURE VS DEPTH - ANEROID GAUGE
Show water pressure versus depth with an aneroid gauge.
Read More
F1-03: PASCAL'S VASES
Show water pressure versus depth with an aneroid gauge.
Read More
F1-04: EQUILIBRIUM TUBES
Demonstrate that pressure is transmitted equally throughout a fluid.
Read More
F1-05: DOES WATER SEEK ITS OWN LEVEL?
A trick to challenge the students.
Read More
F1-06 WATER SEEKS ITS OWN LEVEL
Demonstrate that pressure is dependent only on depth, and not on the shape of the container.
Read More
F1-11: HYDRAULIC PRESS
Demonstrate dramatically Pascal's Law and the large forces attainable using hydraulic systems.
Read More
F1-12: PASCAL'S LAW - COILED TUBE PARADOX
Illustrate Pascal's law in a dramatic way.
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F1-13: CONSTANT WATER PRESSURE
Demonstrate a mechanism which produces a constant water pressure.
Read More
F1-14: PISTON DIAMETER VS TRAVEL - WORKING MODEL
Show that with an incompressible fluid the bigger piston moves more slowly than the smaller piston.
Read More
F1-15: PRESSURE GLOBE
Demonstrate principles of air pressure.
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F1-21: LIPLESS STRAW
Demonstrate the role of atmospheric pressure in the operation of a drinking straw.
Read More
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