PHYS 260 - Demo Use (Total: 296 Demonstrations)
| Demonstration |
Uses |
| C8-11 INTERNAL VS. EXTERNAL ENERGY - SPRING-COUPLED SUPERBALLS |
1 |
| F1-01 FLUID PRESSURE VS. DEPTH |
11 |
| F1-02 FLUID PRESSURE VS. DEPTH - ANEROID GAUGE |
4 |
| F1-03 PASCAL'S VASES |
7 |
| F1-04 EQUILIBRIUM TUBES |
18 |
| F1-05 DOES WATER SEEK ITS OWN LEVEL |
10 |
| F1-06 WATER SEEKS ITS OWN LEVEL |
7 |
| F1-11 HYDRAULIC PRESS |
13 |
| F1-12 PASCAL'S LAW - COILED TUBE PARADOX |
1 |
| F1-13 CONSTANT WATER PRESSURE |
3 |
| F1-14 PISTON DIAMETER VS. TRAVEL - WORKING MODEL |
6 |
| F1-21 LIPLESS STRAW |
2 |
| F2-01 ARCHIMEDES' PRINCIPLE |
18 |
| F2-03 CARTESIAN DIVER - EXPLICIT VERSION |
1 |
| F2-04 BUOYANCY - SPHERE AND WATER |
4 |
| F2-05 BUOYANCY - BOAT AND ROCK |
17 |
| F2-06 BUOYANCY - SINKING BOAT |
1 |
| F2-07 BUOYANCY - PEPSI AND DIET PEPSI |
8 |
| F2-08 BUOYANCY - BATTLESHIP IN BATHTUB |
3 |
| F2-09 BUOYANCY - BALLOON IN HEAVY GAS |
1 |
| F2-11 HYDROMETER |
1 |
| F2-12 HOT AIR BALLOON |
1 |
| F2-21 REACTION TO BUOYANT FORCE |
7 |
| F2-23 BUOYANCY PARADOX- INVERTED BLOCK |
1 |
| F2-31 BUOYANT BALLS IN BEANS |
4 |
| F4-01 VISCOSITY OF LIQUIDS |
2 |
| F4-11 LAMINAR AND TURBULENT FLOW OF AIR |
4 |
| F4-15 FLYING BIRD MODEL |
2 |
| F4-31 SIPHON |
1 |
| F4-32 SIPHON - CHAIN MODEL |
2 |
| F4-63 MARRIOTTE'S BOTTLE |
3 |
| F5-01 BERNOULLI'S PRINCIPLE - TOY CAR AND BALL |
3 |
| F5-03 BERNOULLI'S PRINCIPLE - THIN METAL SHEETS |
4 |
| F5-04 BERNOULLI'S PRINCIPLE - LARGE BALL AND FUNNEL |
2 |
| F5-06 BERNOULLI'S PRINCIPLE - BEACH BALL |
6 |
| F5-07 BERNOULLI'S PRINCIPLE - SPOOL AND CARDBOARD |
3 |
| F5-09 BERNOULLI'S PRINCIPLE - HAIRDRYER AND PING PONG BALL |
1 |
| F5-21 VENTURI TUBE WITH MANOMETERS |
6 |
| F5-22 VENTURI TUBE WITH PING PONG BALLS |
4 |
| G1-01 EXAMPLES OF SIMPLE HARMONIC MOTION |
29 |
| G1-11 COMPARISON OF SHM AND UCM |
14 |
| G1-12 PENDULUM AND ROTATING BALL |
9 |
| G1-13 MASS ON STRING |
1 |
| G1-14 PENDULA WITH DIFFERENT MASSES |
15 |
| G1-15 PENDULA WITH 4 TO 1 LENGTH RATIO |
13 |
| G1-16 PENDULUM WITH LARGE-ANGLE OSCILLATION |
2 |
| G1-20 PENDULUM RELEASE CONUNDRUM |
1 |
| G1-31 HOOKE'S LAW AND SHM |
6 |
| G1-32 MASS ON SPRING - WITH STAND |
6 |
| G1-33 MASSES AND SPRINGS WITH SPIDER |
9 |
| G1-35 MASS ON SPRING - EFFICIENT MODEL |
7 |
| G1-36 MASS ON SPRING WITH FORCE MEASUREMENT |
5 |
| G1-37 MASS ON SPRING WITH ULTRASONIC RANGER |
1 |
| G1-41 TORSIONAL PENDULUM - SMALL |
3 |
| G1-42 TORSIONAL PENDULUM - LARGE |
2 |
| G1-51 INVERTED SPRING PENDULUM |
2 |
| G1-52 STRINGLESS PENDULUM |
9 |
| G1-53 SHM - CAN IN WATER TANK |
6 |
| G1-58 LOADED PENDULUM |
1 |
| G1-60 CHAOS - TWO BIFILAR PENDULA |
5 |
| G1-82 PENDULUM WAVES |
2 |
| G1-83 PENDULUM WAVES - COMM'L VERSION |
1 |
| G2-01 MASS ON SPRING - HAND HELD |
18 |
| G2-02 FORCED HARMONIC MOTION WITH DAMPING - LARGE |
17 |
| G2-03 RESONANCE IN TORSIONAL PENDULUM - PROJECTION |
3 |
| G2-04 DAMPED OSCILLATIONS |
7 |
| G2-07 PSYCHOACOUSTIC VIBRATION TRANSDUCER |
1 |
| G2-11 RESONANT SAW BLADES - HAND DRIVEN |
5 |
| G2-12 BARTON'S PENDULUMS |
3 |
| G2-21 COUPLED PENDULA |
5 |
| G2-23 SPRING-COUPLED PHYSICAL PENDULA |
1 |
| G2-24 COUPLED PENDULA - 100 TO 1 MASS RATIO |
1 |
| G2-41 WILBERFORCE PENDULUM |
4 |
| G3-01 SHIVE WAVE MACHINE - TRAVELING WAVES |
22 |
| G3-02 SHIVE WAVE MACHINE - SUPERPOSITION OF PULSES |
1 |
| G3-03 SHIVE WAVE MACHINE - REFLECTION OF PULSES |
3 |
| G3-04 SHIVE WAVE MACHINE - STANDING WAVES |
8 |
| G3-21 TRANSVERSE WAVES ON A LONG SPRING |
17 |
| G3-23 TRANSVERSE WAVES ON A LONG SPRING - FREE END |
4 |
| G3-24 SLINKY ON LECTURE TABLE - TRAVELING WAVES |
5 |
| G3-25 SLINKY ON LECTURE TABLE - IMPEDANCE MISMATCH |
1 |
| G3-26 AIR TRACK - LONGITUDINAL WAVES |
1 |
| G3-28 SUSPENDED SLINKY |
14 |
| G3-29 SUSPENDED SLINKY - PORTABLE |
3 |
| G3-41 WAVE MODELS - PROJECTION |
2 |
| G3-42 TORSIONAL WAVES |
4 |
| G3-43 WHIP |
3 |
| G3-44 WAVE-DRIVEN BUMPER JACK |
7 |
| G3-51 ROPE WAVE GENERATOR - FREQUENCY VS. WAVELENGTH |
31 |
| G3-52 ROPE WAVE GENERATOR - ROPE TENSION VS. WAVELENGTH |
23 |
| G3-53 STANDING WAVES IN A STRING |
4 |
| G4-22 CHLADNI FIGURES - OSCILLATOR DRIVEN |
3 |
| H1-01 BELL IN VACUUM |
15 |
| H1-02 SPEAKER AND CANDLE |
9 |
| H1-03 BELL IN VACUUM - PORTABLE |
1 |
| H1-03 BELLS |
1 |
| H1-11 MICROPHONE AND OSCILLOSCOPE |
2 |
| H1-12 VISIBLE WAVEFORMS ON LARGE SPEAKER |
1 |
| H1-13 WAVEFORM GENERATOR, SPEAKER AND OSCILLOSCOPE |
3 |
| H1-21 SPEED OF SOUND - PHASE CHANGE |
4 |
| H1-22 SPEED OF SOUND - USING PULSES |
8 |
| H1-23 SPEED OF SOUND IN ALUMINUM |
2 |
| H1-24 SPEED OF SOUND IN HELIUM |
1 |
| H1-31 SOUND LEVEL METER |
1 |
| H1-32 WAVETEK AND AUDIO CART - EQUAL SOUND LEVEL STEPS |
1 |
| H1-41 ULTRASONIC MOTION DETECTOR |
3 |
| H1-43 ULTRASONICS AND HEARING |
6 |
| H2-02 PARABOLIC MICROPHONE |
4 |
| H2-21 AUDIBLE YOUNG'S EXPERIMENT - GROUP LISTENING |
11 |
| H2-22 INTERFERENCE - TRANSPARENCIES |
4 |
| H2-23 INTERFERENCE - KLINGER TRANSPARENT SLIDES |
4 |
| H2-26 PHASE REVERSAL BETWEEN STEREO SPEAKERS |
5 |
| H2-28 FOURIER SYNTHESIZER - ADDITION OF WAVES |
6 |
| H2-31 ACOUSTIC COLLIMATOR |
1 |
| H2-32 SPEAKER WITH BAFFLE |
5 |
| H2-41 DOPPLER BALL |
23 |
| H2-42 DOPPLER EFFECT - TUNING FORK ON STRING |
8 |
| H2-51 BEATS - AUDIO OSCILLATORS, SPEAKERS & OSCILLOSCOPE |
13 |
| H2-52 BEATS AND RESONANCE - TUNING BARS |
2 |
| H2-53 BEATS - AUDIO OSCILLATORS AND SPEAKERS |
10 |
| H2-55 BEATS AND RESONANCE - TUNING BOXES |
2 |
| H3-02 STANDING SOUND WAVES - REFLECTION |
3 |
| H3-04 KUNDT'S TUBE - STROKED ROD |
1 |
| H3-05 KUNDT'S TUBE - OSCILLATOR DRIVEN |
1 |
| H3-11 TUNING FORKS AND RESONANT TUBE |
2 |
| H3-13 ROARING TUBE - 8 FT |
1 |
| H3-14 TWIRL-A-TUNE |
3 |
| H3-15 TWIRL-A-TUNE AND VACUUM CLEANER |
5 |
| H3-17 FLAME TUBE |
5 |
| H3-21 SOUND RESONANCE IN WATER TUBE |
3 |
| H3-22 RESONANCE TUBE - OSCILLATOR AND PLUNGER |
1 |
| H3-23 RESONANCE TUBE - OSCILLATOR, PLUNGER & MICROPHONE |
5 |
| H3-24 OPEN AND CLOSED PIPES |
9 |
| H3-31 DUCK CALL |
1 |
| H3-32 RESONANCE IN TUBE - POURING WATER |
3 |
| H3-61 BEAKER BREAKER |
13 |
| H3-71 STROKED ALUMINUM ROD |
6 |
| H4-01 FOURIER SYNTHESIS |
5 |
| H4-04 FOURIER ANALYSIS - DIGITAL OSCILLOSCOPE |
1 |
| H4-23 SOUND BOARD - TUNING FORK AND LECTURE TABLE |
1 |
| H6-04 HELIUM VOICE |
4 |
| H6-05 SULFUR HEXAFLUORIDE VOICE |
2 |
| I1-01 THERMOMETERS |
5 |
| I1-11 THERMAL EXPANSION - BALL AND HOLE |
12 |
| I1-12 THERMAL EXPANSION - BALL AND RING |
8 |
| I1-13 THERMAL EXPANSION - BIMETAL STRIP |
14 |
| I1-15 THERMAL EXPANSION - PIN BREAKER |
7 |
| I1-17 THERMOSTAT - MODEL |
3 |
| I1-19 LAVA LAMP |
4 |
| I1-21 WATER NEAR 4 DEGREES CELCIUS |
1 |
| I1-32 RUBBER BAND CONTRACTION DURING HEATING |
2 |
| I1-42 THERMOELECTRIC FAN |
2 |
| I1-51 RUBBER AT LN TEMPERATURE |
3 |
| I1-52 TUNING FORK AT LN TEMPERATURE |
1 |
| I1-53 LEAD BELL AT LN TEMPERATURE |
6 |
| I2-01 CROOKES' RADIOMETER |
1 |
| I2-04 WIEN'S LAW OF THERMAL RADIATION |
6 |
| I2-08 RADIATIVE HEAT TRANSFER |
4 |
| I2-09 DEWAR - TRANSPARENT WITH LN |
5 |
| I2-11 THERMOS BOTTLE |
1 |
| I2-12 RADIATION FROM COLD OBJECT |
1 |
| I2-21 THERMAL CONDUCTIVITY IN METALS |
12 |
| I2-23 THERMAL CONDUCTIVITY IN METALS - PROJECTION |
1 |
| I2-24 THERMAL CONDUCTIVITY IN WATER |
1 |
| I2-26 LEIDENFROST PHENOMENON |
1 |
| I2-41 CONVECTION - POWDER IN WATER |
1 |
| I2-43 CONVECTION - HOT PLATE |
6 |
| I2-44 CONVECTION - CANDLE IN CYLINDER |
1 |
| I3-16 COLLAPSE OF CAN - LARGE PUMP |
5 |
| I3-32 ISOBARIC EXPANSION OF AIR |
2 |
| I3-33 HELIUM BALLOON ON LIQUID NITROGEN |
6 |
| I3-41 BOYLE'S LAW - PROJECTION |
10 |
| I3-51 CHARLES' LAW - PROJECTION |
7 |
| I3-52 CONSTANT VOLUME GAS THERMOMETER - ABSOLUTE |
9 |
| I4-03 LATENT HEAT - ICE TO WATER TO STEAM |
11 |
| I4-12 BOILING WATER BY PUMPING |
2 |
| I4-13 CHANGE OF STATE OF LN - POPPING CAN LID |
6 |
| I4-15 CONDENSATION OF STEAM - GALLON CAN COLLAPSE |
5 |
| I4-17 AIR BALLOON ON LIQUID NITROGEN |
3 |
| I4-19 CONDENSATION OF STEAM - SODA CAN COLLAPSE |
1 |
| I4-31 ICE BOMB |
5 |
| I4-32 FREEZING WATER BY PUMPING |
3 |
| I4-35 LOWERING THE FREEZING POINT OF WATER USING SALT |
2 |
| I4-51 SUBLIMATION OF DRY ICE - PROJECTION |
5 |
| I5-01 MECHANICAL EQUIVALENT OF HEAT - SHOT BAG |
3 |
| I5-02 TRANSFORMATION OF MECHANICAL ENERGY INTO HEAT |
1 |
| I5-03 MECHANICAL EQUIVALENT OF HEAT - JOULE'S METHOD |
3 |
| I5-11 ADIABATIC PROCESS - AIR PISTON WITH THERMISTOR |
10 |
| I5-12 ADIABATIC EXPANSION OF AIR - FOG IN BOTTLE |
4 |
| I5-13 ADIABATIC EXPANSION OF AIR - GRAPH OF TEMP |
2 |
| I5-14 LIQUEFICATION OF NITROGEN |
2 |
| I5-15 ADIABATIC EXPANSION OF CARBON DIOXIDE |
6 |
| I5-22 FIRE SYRINGE |
4 |
| I5-31 STEAM ENGINE - STATIONARY |
3 |
| I5-32 STIRLING ENGINE |
2 |
| I5-33 STEAM ROLLER |
7 |
| I5-34 STIRLING ENGINE - VISIBLE |
6 |
| I5-41 ENDOTHERMIC REACTION - ENTROPY |
1 |
| I5-51 SPECIFIC HEAT - ALUMINUM AND COPPER |
6 |
| I5-52 ELECTRIC CALORIMETER |
1 |
| I6-01 GAS PRESSURE - MODEL |
14 |
| I6-03 EQUIPARTITION OF ENERGY |
6 |
| I6-11 BROWNIAN MOTION WITH TV |
7 |
| I6-21 GAS DIFFUSION - MODEL |
4 |
| I6-23 DIFFUSION - FOOD COLOR IN WATER |
3 |
| I6-25 DIFFUSION - DISTRIBUTION OF PING-PONG BALLS |
1 |
| I6-26 DIFFUSION - PERFUME |
3 |
| I6-31 MOLECULAR MOTION DEMO - BROWNIAN MOTION |
1 |
| I6-32 MOLECULAR MOTION DEMO - RANDOM MOTION IN GASES |
5 |
| I6-33 MOLECULAR MOTION DEMO - GAS PRESSURE |
2 |
| I6-34 MOLECULAR MOTION DEMO - TEMPERATURE OF A GAS |
4 |
| I6-38 MOLECULAR MOTION DEMO - BOYLE'S LAW |
1 |
| I6-39 MOLECULAR MOTION DEMO - CHARLES' LAW |
1 |
| I6-40 MOLECULAR MOTION DEMO - SOLIDS |
3 |
| I6-41 MOLECULAR MOTION DEMO - LIQUIDS |
1 |
| I6-51 ENTROPY - SORTING MARBLES |
4 |
| I6-52 ENTROPY - FOUR BALLS IN GAS DIFFUSION MODEL |
1 |
| I6-61 MAXWELL DEMON |
1 |
| I7-21 SUPERCONDUCTIVITY - MAGNET LEVITATION |
2 |
| J1-01 TRIBOELECTRICITY - CHARGING BY FRICTION |
9 |
| J1-03 KILOVOLT CARPET |
5 |
| J1-05 CHARGED BALLOONS |
10 |
| J1-11 ELECTROPHORUS |
5 |
| J1-12 INDUCTION - ELECTROSCOPE |
12 |
| J1-13 ELECTROSTATIC INDUCTION |
2 |
| J1-21 ELECTROSTATIC ATTRAC AND REPULS - CHARGED CYLINDERS |
14 |
| J1-22 ELECTROSTATIC ATTRAC AND REPULS - WIMSHURST MACHINE |
5 |
| J1-24 ELECTROSTATIC HAIR RAISING |
9 |
| J1-25 VAN DE GRAAFF - TRAINED RABBIT |
7 |
| J1-26 VAN DE GRAAFF - REPULSION OF PIE PANS |
4 |
| J1-28 COULOMBS LAW - PROJECTION |
2 |
| J1-41 CONDUCTORS AND INSULATORS |
5 |
| J2-03 VAN DE GRAAFF GENERATOR WITH GROUND SPHERE |
7 |
| J2-11 FRANKLIN'S WHEEL |
1 |
| J2-13 PLASMA MACHINE - EYE OF THE STORM |
2 |
| J2-14 LIGHTNING ROD SIMULATOR |
4 |
| J2-15 ELECTROSTATIC SMOKE PRECIPITATOR |
3 |
| J2-16 ELECTRODELESS GAS DISCHARGE |
1 |
| J2-31 JACOB'S LADDER |
1 |
| J2-32 JACOB'S LADDER - PORTABLE |
3 |
| J2-33 TESLA COIL - PORTABLE |
4 |
| J3-01 EXISTENCE OF ELECTRIC FIELDS |
5 |
| J3-02 ELECTRIC FIELD OF RING OF CHARGE - MODEL |
8 |
| J3-03 ELECTRIC FIELD LINES |
10 |
| J3-04 ELECTRIC FIELD LINES - SOAP BUBBLES |
1 |
| J3-05 VAN DE GRAAFF - INDUCTION WITH SPHERES AND NEON BULBS |
1 |
| J3-06 ELLIPSOIDAL CONDUCTOR |
8 |
| J3-07 VAN DE GRAAFF - DISCHARGE TO VARIOUS RADII |
5 |
| J3-08 VAN DE GRAAFFS - INTERACTING FIELDS |
2 |
| J3-11 EQUIPOTENTIALS/LINES OF FORCE - ONE CHARGE |
11 |
| J3-12 EQUIPOTENTIALS/LINES OF FORCE - TWO POSITIVE CHARGES |
4 |
| J3-13 POTENTIAL SURFACE MODEL WITH E FIELD VECTORS |
3 |
| J3-14 FLUX MODEL - ELECTROSTATICS |
9 |
| J3-21 FARADAY CAGE |
12 |
| J3-22 FARADAY CAGE - ELECTROSCOPE |
7 |
| J3-23 FARADAY CAGE - RADIOWAVES |
11 |
| J3-24 HOLLOW CONDUCTING SPHERE |
11 |
| J4-01 PARALLEL PLATE CAPACITOR |
19 |
| J4-02 PARALLEL PLATE CAPACITOR - SYMMETRIC |
1 |
| J4-03 PARALLEL PLATE CAPACITOR - SERIES CAPACITORS |
5 |
| J4-04 PARALLEL PLATE CAPACITOR - IONIZATION OF AIR |
4 |
| J4-11 POLAR AND NONPOLAR LIQUIDS |
1 |
| J4-12 ELECTROSTATIC FORCE - MOVING LUMBER |
1 |
| J4-21 COLOR FILTER MODEL OF CHARGED DIELECTRIC |
2 |
| J4-22 PARALLEL PLATE CAPACITOR WITH DIELECTRIC |
8 |
| J4-24 FORCE ON DIELECTRIC IN ELECTRIC FIELD |
2 |
| J4-31 ENERGY STORED IN A CAPACITOR |
7 |
| J4-32 DISCHARGE OF CAPACITOR WITH BANG |
12 |
| J4-41 CAPACITORS |
8 |
| J4-42 CAPACITORS IN SERIES AND PARALLEL |
4 |
| J4-51 THEREMIN |
3 |
| K2-62 ELECTROMAGNETIC CAN SMASHER |
1 |
| K5-12 BATTERY AND CURRENT - WORKING MODEL |
2 |
| K5-13 ELECTRIC CURRENT - MODEL |
9 |
| K5-14 ELECTRIC CELL |
1 |
| K5-31 OHM'S LAW |
8 |
| K5-32 RESISTANCE VS DIAMETER AND LENGTH |
2 |
| K5-33 CONDUCTIVITY OF SALT SOLUTION |
1 |
| K5-34 THERMAL COEFFICIENT OF RESISTANCE IN COPPER |
2 |
| K5-35 RESISTORS AT LN TEMPERATURE |
1 |
| K5-36 RESISTORS AT LN TEMPERATURE - LIGHT BULB INDICATOR |
7 |
| K5-41 V-I CURVES FOR OHMIC AND NON-OHMIC DEVICES |
2 |
| K5-43 NON-OHMIC DEVICE - V VS. I |
2 |
| K5-44 NON-OHMIC DEVICE - LIGHT BULB |
4 |
| K6-01 SERIES AND PARALLEL LIGHTS - TWO BULBS |
7 |
| K6-02 SERIES AND PARALLEL LIGHTS - FIVE BULBS |
9 |
| K6-03 SERIES AND PARALLEL LIGHTS - BATTERY AND CLIP-ON WIRES |
1 |
| K6-11 CIRCUIT PARADOXES |
10 |
| K6-12 SERIES/PARALLEL LIGHT CIRCUIT CONUNDRUM |
1 |
| K6-33 WHEATSTONE BRIDGE |
1 |
| K6-34 METER WITH SHUNTS AND MULTIPLIERS |
2 |
| K6-35 VOLTAGE DIVIDER |
1 |
| K6-52 IMPEDANCE MATCHING - BATTERY AND |
2 |
| K7-11 RC CIRCUIT - RC TIME CONSTANT - |
2 |
| K7-12 RC CIRCUIT - RC TIME CONSTANT - PROJECTION METERS |
1 |
| K7-13 RC CIRCUIT - RC TIME CONSTANT - STORAGE SCOPE |
1 |