From: William Maddox

                           AUBURN PHYSICS DEPARTMENT
                DEMONSTRATIONS UPDATE  FALL 2006 

                            PHYSICS IS AN EXPERIMENTAL SCIENCE
                              DON'T JUST TALK ABOUT IT. DO SOMETHING.

Most of the demonstrations available are described in the Resources > Demonstration Page section of the Physics Department web site. Some new and changed demonstrations are described below. A new version of the web site material is available on the computer in the Demo Room. Astronomy and Modern Physics sections have been added since site was created. This Summer and Fall a large number of changes are being made to mechanics, E&M, fluids, and thermodynamics sections. Other sections will be changed next summer. The answer to the question How do you get to Carnegie Hall? is practice, practice. The same advice applies to doing demonstations. Consider using demonstrations in upper level courses instead of another long boring derivation.

CHANGES TO DEMONSTRATIONS ON DEPARTMENT WEB SITE AND EQUIPMENT

1. Constant speed cart versus accelerated cart available.
2. A new device is available to measure speeds such as Bozack's hand just before it hits the board in his karate demonstration.
3. Fur is available for use in electrostatics.Use at your own risk. Not responsible for attacks by animal rights advocates.
4. A safer and better looking Jacob's ladder device is available to replace homemade version. Use as visual aid in talking about voltage, resistance, lightning and hot air rising.
5. A CD containing the black and white movie of muon decay in atmosphere showing special relativity effect on time is available. Some of you may have seen this movie as a student. Length ~ 35 minutes.
6. Device to visually demonstrate current flow is available. It could be used with generators and motors. In case you were wondering electrons are red.
7. New Power of Ten Video. Somewhere between galaxies and atom, pause to look at satellite photo of Southeast. This is on a web site. Go to http://micro.magnet.fsu.edu/primer/java/scienceopticsu/powersof10/.
8. A ratemeter with sound is available to replace the increasingly erratic geiger counter.
9. Glycerin is available for making soap films last longer. Anisole back in stock for use in disappearing eyedropper demo.
10. A new version of the setup to show electric field between parallel plates is in use.
11. Visual Acceleration Cart. Leds on the side of the cart show amount of acceleration. Red and green to show direction. Put on inclined plane to show how component of gravity along incline decreases as angle decreases.
12. For those who want to make a laser beam visible but don't want to mess up everything with chalk dust, we now have "fog in a can".
13. A video tape of the physics of car crashes is available. Emphasis on momentum.
14. "Buzzing " magnets available. Toss them in air. They will attract each other and come together making sound. Useful as visual aid to start section on magnetism.
15. Two plasma devices are available that produce miniature lightning bolts. Pattern changes if you touch device. Smaller battery powered version can be passed around.
16. A flashlight is available that uses a capacitor charged up by moving a magnet back and forth through a coil instead of batteries. Uses the idea that an EMF is induced in the coil by changing magnetic field (one of Faraday's contributions to E&M).
17 A solar powered vehicle is available for use in discussing energy transformation: light>electricity>kinetic + friction.
18. A fan cart is now available. Air from fan can be partly or completely blocked. Which way will it move? Think about momentum conservation.
19. New devices are available to show magnetic field around single wire, coil & solenoid. These are for use on overhead projector and use small transparent base compasses to show field.


              NEW  DEMONSTRATIONS NOT ON WEB SITE
    

                                 Mechanics
 

1. 1N30.50 LINEAR MOMENTUM:COLLISIONS  New device for discussing momentum conservation in collisions. If sharp point hits board it will wobble but not fall over. If the sharp point is removed so rubber ball hits board  it is knocked over easily. Why does it fall over even though moving object has less mass hence less momentum?
2. 1F10.20 NEWTON'S FIRST LAW:INERTIA VERSUS WEIGHT  Have students come up to front desk and lift and move horizontally what looks like a regular Pepsi can. It is filled with lead so a noticeable force is needed to move it horizontally as well as lift it. Compare to empty can and can filled with Pepsi.
3. 1Q40.05 ROTATIONAL DYNAMICS:ANGULAR MOMENTUM This demo simulates what happens when a helicoper takes off. A fan  starts turning. The device has acquired angular momentum using an internal power supply. To compensate the entire device starts spinning in opposite direction. If you tilt the fan you can show how a helicopter moves foward also.
4. 1Q50.15 ROTATIONAL MECHANICS: PRECESSION. This demo involve device called Euler's Disk. This can be used as a small scale demonstration of precession. Unlike the large bicycle demo of precession, the disk slowly falls over. It thus also demonstrates conversion of gravitational potential energy to rotational kinectic enegy. The frequency of the sound you hear increases just before disk comes to halt.
5. 1Q50.21 ROTATIONAL MECHANICS: PRECESSION. Another way of demonstrating precession is to suspend a spinning wheel using a rope attached to one end of a rod passing through center of wheel. Practice this one before class.
6. 1D60.35 MOTION IN 2 DIMENSIONS: PROJECTILE MOTION    A device is available to show how range varies with angle. Projectile falls on desk. Put something on desk to mark where projectile lands for different angles.
7. 1Q20.50NEWTON'S SECOND LAW: COMPLEX SYSTEMS A device is available to demonstrate the standard textbook problem that shows that a falling object can have an acceleration > g. This is called the hinged stick device. It is related to falling chimney problem.
8. 1H10.15 NEWTON'S THIRD LAW As a way of demonstrating action-reaction we have a small boat that shoots water out a tube on the back. Use it in one of the fishtanks used for optics demos. Stand clear once you start boat. Have towel ready.
9. 1Q40.40 ROTATIONAL DYNAMICS:ANGULAR MOMENTUM  Use train on  turntable to illustrate conservation of angular momentum. Train goes one way, turntable rotates in opposite direction.
10. 1R40   PROPERTIES OF MATTER: COEFFICIENT OF RESTITUTION Bounce/No Bounce: Balls look the same. One bounces. One does not. Use when talking about coefficient of restitution or energy conversion (PE>KE> heat and sound).


                                    Fluids

1. As an attention getting but messy way of introducing fluids try this. Put a warm 2 liter bottle of diet Coke in the sink. Add 2 pieces of Mentos candy. Get out of the way. The contents will shoot up in the air. You may want to move students away from sink. Have a towel available. This is not a chemical reaction.The carbon dioxide rapidly leaves the liquid. Physicists still debating surface tension reduction versus nucleation sites. Bring your own diet Coke. Mentos in stock. 
2. 2B20.50 STATICS OF FLUIDS:STATIC PRESSURE   Pascal's Principle device. Push on plunger. Pressure will be transmitted throughout fluid causing it to squirt out holes. Safety Hazard: angry wet students.
3. 2B40.54 STATICS OF FLUIDS: DENSITY & BUOYANCY  What determines whether an object sinks or floats? As a visual aid put a can of Classic Coke and a can of Diet Coke in one of our "fish tanks". The Classic Coke can will sink. The Diet Coke can will float. Pepsi version also available.
4. 2B40.71 STATICS OF FLUIDS:DENSITY & BUOYANCY  Demo has three liquids with different densities and objects of different densities floating at different levels. Assembled as needed.
5. 2B40.59 STATICS OF FLUIDS:DENSITY & BUOYANCY Another way to demonstrate connection between density and floating. Color hot water with yellow food coloring. Color cold water with blue food coloring. Fill cylinder about 2/3 full with cold water. Slowly add hot water until full. The top half will turn green where the water mixes. The bottom half stays blue. The warm mixture floats on the cold bottom layer.
6. 2C20.45 DYNAMICS OF FLUIDS: BERNOULLI PRINCIPLE . Hang two bowling balls from metal rod so they are a few inches apart. Use a leaf blower to blow air between them. Which way will they move?
7. 2C50.10 DYNAMICS OF FLUIDS: VORTEX  Use device to produce smoke rings. The ring has a low pressure area at the center. Compare to hurricanes. Useful as attention getting device.


                     Waves & Oscillations

1.3A60.15 OSCILLATIONS: MECHANICAL RESONANCE  A model showing the torsional vibration that destroyed the Tacoma Narrrows bridge is available to supplement the movie. Assembled as needed. Need a day advance notice to assemble and test.
2. 3B60.20 WAVE MOTION: BEATS  A beat note demonstation is available that uses two function generators, scope and speaker. This should be loud enough to use in large classrooms and you won't have to keep banging on tuning forks. At least 1 day notice needed to assemble and test.
3. If you want to demonstrate beats in one of the larger classrooms, a CD is also available for use in computer. You need to know how to play audio CD using Windows Media Player.
4. 3A60.40 OSCILLATIONS: DRIVEN MECHANICAL RESONANCE Signal generator connected to spring can be varied in frequency to show resonance in driven system. Assembled as needed.
5. 3B22.11 WAVE MOTION: STANDING WAVES  Attach metal ring to vibrator. Drive with signal generator until resonance occurs.Start around 20 Hz. Three, five and seven anti-nodes can be produced. CD version available.
6. 3B22.12 WAVE MOTION: STANDING WAVES  Show standing waves using long string setup on desk top. Helps if class meets in 307 and class meets at 8AM.

                            Thermodynamics

1.4B30.23 HEAT: CONDUCTION  Put ice cubes on two nearly identical blocks. One will melt much faster. Talk about Q=mc(delta T), Q=mL, and conductivity. One block is aluminum painted black to look like other material. Other material has low heat conductivity.
2. 4B40.10 HEAT : RADIATION  Use metal mirrors with about one foot diameter. Place heating coil about 9-10 cm from concave mirror. Use jack stand to center coil. Place second mirror about 1 meter  from first mirror. Use rods and clamps to place match about 9 -10 cm from second mirror. Adjust mirrors and match so orange light relected by second mirror shines on the match head. You may have to turn out lights near setup to see light on matchhead. The match will start smoking and then burst into flame. You may want to turn out all light when you see matchhead start smoking.
3. 4A30.12 THERMAL PROPERTIES:EXPANSION  Expanding wire demo. Length of wire increases when heated. Pointer moves along scale.
4. 4B60.15 HEAT AND FIRST LAW:CONVERSION OF K.E. TO HEAT. Put a piece of paper over large metal ball and hit it with the other ball. Enough kinetic energy will be converted to heat to burn a hole in paper. In smaller classes do several times and pass paper around so students can smell that paper is burned not just torn.
5. 4B20.25 HEAT: CONVECTION  Symmtery Breaking and Convection. If lit candle is covered with a long tube it will go out. All the oxygen near candle is used up. Rising hot gases prevent more air from coming in. Put a divider in midddle of tube and try again. There is so much air flow it blows flame around. Some small random difference converts symmetric situation into one with hot gases going up one side and fresh air going down other side of tube.
6. 4F10.46 ENTROPY  Exploding fuel demo ( like in car engine). A small amount of methanol is placed in a plastic bottle. Put on top and swirl around to fill space with vapor. Replace screw on cap with cork. Use hand held tesla coil to apply high voltage to screw in side of bottle. Blue flame and loud explosion occur. Cork heads toward ceiling. Wear eye protection. Try this out ahead of time so you will know what to expect.
7. 4B10.20 HEAT: HEAT CAPACITY  See color mixing demo under fluids. Serves as example of what happens when you bring objects at different temperatures in contact and as example of irreversable process.
8. 4B30.50 HEAT: CONDUCTIVITY Liquid nitrogen cannon: Besides intended use, also useful in discussing frost/dew formation or as example of conduction in metal. One day advance notice needed or bring your own LN. 9.
9. 4B40.40 HEAT:RADIATION   Demonstrate that good absorbers are good emitters. Put hot water in a silver can and a blck can. Record temperature. Keep checking and recording temperature. The black can should cool faster.
10. 4D20.11  KINETIC THEORY: RADIOMETER.  The idea that dark surfaces are better emitters than light surfaces can also be demonstrated using the radiometer. Use the hot air blower to heat it until it is spinning rapidly. Let it cool off. It will come to a stop and slowly rotate in the reverse direction.



Electricity & Magnetism

1. 5C30.31  CAPACITANCE: TIME CONSTANT  Variation of capacitor and bulb uses 5 bulbs to visually show how changing resistance affects decay time. A capacitor is charged from 6V battery. It is then discharged through light bulb(s).
2. 5F30.20 RC CIRCUITS: TIME CONSTANT  An oscilloscope version of  capacitor & bulb is available. Shows exponential charging or discharging curve. Also can be used with inductor instead of capacitor. At least 1 day  notice needed to assemble and test
3. 5C10.21 CAPACITANCE: EFFECT OF SPACING   The change in capacitance due to changing plate separation can be demonstrated using digital multimeter that measures capacitance. The output can be sent to a computer and displayed on movie screen.
4. 5H20.05 MAGNETIC FIELDS & FORCE:FORCES ON MAGNETS  The effect of the Earth's magnetic field on a magnet can be demonstrated by rolling a small but strong disc shaped magnet down an incline. Instead of rolling straight down the magnet will curve to left or right depending on orientation.
5. 5C30.35 CAPACITANCE: CHARGING CAPACITOR. Hook a generator to the 1 farad capacitor(5v limit). Note that as you turn the handle it becomes easier as the capacitor charges up. The rate at which the voltage changes is reduced. If you let go, the handle will continue to turn. Ask class to explain why torque needed is reduced, why charging rate goes down, why handle turns, and which way will it turn.. Device to visually demonstrate current flow could be used with this demonstration.
6. 5B10.45 ELECTRIC FIELD & POTENTIAL A model of a molecule lining up in an electric field is available. Two balls on the ends of a rod are placed between plates of a capacitor. The capacitor is charged using a Van de Graff generator. The rod is initially placed at right angles to field. Can be used to explain why charged rod bends water and grass seed floating in oil line up with field.
7. 5B10.35 ELECTRIC FIELD & POTENTIAL A variation on this idea of initially uncharged objects being attracted by charged objects  involves having a metal ball bounce back and forth between plates connected to ground and sphere of Van de Graff generator. One version of this is called Ben Franklin's bells.
8.  5H30.56 MAGNETIC FORCES: FORCES ON CURRENT  Besides bending water with a charged rod you can make water move using a magnet. At least 1 day notice needed to assemble and test. Aluminum foil is placed aroung the edge of a container of salt water. It is placed between the poles of a magnet. An electrode is placed in the center. A car battery is connected to the electrode and the aluminum foil. The magnet exerts a force on the current between the foil and center electrode. As a side effect electrolyis also occurs.
9. 5A20.15 ELECTROSTATICS: COULOMB'S LAW  A device is availble to demonstrate the force between charged objects. At least 1 day notice needed to assemble and test. One metal plate is connected to ground. Another plate connected to a spring is suspended several centimeters above grounded plate. This plate is connected to sphere of Van de Graff. The plates will acquire opposite charges. The one on spring will move down until it touches other plate and charge is neutalized. The spring will then pull the plates apart.
10. 5H20.22 MAGNETIC FORCES: FORCES ON MAGNETS  Objects suspended using static electric or magnetic fields are usually considered examples of unstable equilibrium. We have a device that uses two plates of diamagnetic material to stabilize a small magnet levitated using a magnetic field.
11. 5G30.10 MAGNETIC MATERIALS: DIAMAGNETISM  As another example of diamagnetism grapes are placed on opposite ends of a small rod. The rod is suspended using thread. A strong magnet brought near a grape will repel it causing the rod to rotate. Bring your own grapes.
12. 5N30.11 ELECTROMAGNETIC RADIATION: SPECTRUM. Instead of using projector as light source to produce spectrum with prism use the overhead projector. Cover most of the plate with paper leaving a narrow slit. Hold prism or grating nears lens of projector.
13. 5D10.40 RESISTANCE:CHARACTERISTICS  The small bed of nails can be used as model of electrical resistance. Use small ball to represent electron. Nails represent atoms.
14. 5L10.10  AC CIRCUITS:IMPEDANCE  Show the effect of inductance on "AC resistance" (impedance). A flashilght bulb is connected in series with the jumping ring coil . A Variac is used to supply ~ 6v AC. The brightness of the bulb will vary as you move the iron core in and out of the coil.
15. 5K40.41 ELECTROMAGNETIC INDUCTION: MOTOR & GENERATOR  Bare bones motor/generator. Magnetic field can be provided by large coils or large permanent magnet. When used with op amp circuit you can generate currrent using Earth's magnetic field.
16. 5K40.71 ELECTROMAGNETIC INDUCTION: MOTOR ACTS AS GENERATOR  Attach an AC voltmeter to DC Motor. The AC meter will not respond to DC current used to operate motor. The AC meter will show a rising voltage (pulsating DC) as the motor speed increase.
17. 5K10.15 ELECTROMAGNETIC INDUCTION: DEMONSTRATE EMF=BLV  Attach wire to rods. Place large magnet so wire is between poles. Attach cable to each end of wire and connect to oscilloscope. Pull on wire and let go. A distorted and damped sine wave will appear on the oscilloscope. Some trial and error need to adjust volt/div and time/div controls.Advance notice needed.
18. 5K40.15 ELECTROMAGNETIC INDUCTION: FARADAY'S MOTOR   One of the small but strong magnets is placed in the center of a pool of mercury. A rod is suspended so one end is in the mercury. Aluminun foil is placed aroung the edge of the container. A DC power supply is connected to the  foil and upper end of rod. The rod will move due to force exterted by magnet on current. Assembled as needed.
19. 5K10.25 ELECTROMAGNETIC INDUCTION: EMF DUE TO CHANGING FLUX . A flashlight is available that uses a capacitor charged up by moving a magnet back and forth through a coil instead of batteries. Uses the idea that an EMF is induced in the coil by changing magnetic field (one of Faraday's contributions to E&M).
20. 5A30.10 ELECTROSTATICS: CONDUCTORS VS INSULATORS. Use the Van de Graff to illustrate the difference between conductors and insulators. Put aluminun foil on base of one of the devices with red or yellow threads. Put the other one on top of the Van de Graff and note how long it takes to charge up and threads to stick out. Repeat with the one with foil.


                                     Optics

1. 6A60.20 RAY TRACING: THICK LENS IN WATER  Instead of filling the air with chalk dust to show laser beam, put a thick lens under water. Add a small amount of non-dairy creamer to make laser beam visible. Why thick lens? What happens if "lens" is filled with air rather than being solid glass?
2. 6A40.45 GEOMETRIC OPTICS: INDEX OF REFRACTION A mirage like effect can be demonstrated by shining a laser through a water-sugar mixture. On top is water only. On bottom is water with a large amount of sugar in it. A laser beam pointed slightly upwards will be bent downwards. Advance notice needed to prepare solution.
3. 6A44.41 GEOMETRIC OPTICS: TOTAL INTERNAL REFLECTION. Shine laser beam from the brighter red laser on edge of notch on one end of cylinder. Internal reflection will cause the beam to spiral around the cylinder.
4. 6A40.30 GEOMETRIC OPTICS: INDEX OF REFRACTION  Now you see it. Now you don't. Pour some Wesson Oil into a clear container. Put a pyrex test tube in the oil. Fill the test tube partly with Wesson Oil. The part that is filled with Wesson Oil will seem to disappear. Another version using anisole and an eyedropper is also available.
5. 6D20.11 INTERFERENCE: GRATING    Shine red and green laser through diffraction grating at same time to show how pattern vaires with wavelength
6. 6A40.47 GEOMETRIC OPTICS: REFRACTION. Demonstrate " twinkle twinkle little star" by putting slide of constellation in slide projector and adjusting so beam passes just over top of hot hotplate. 

 


                               ASTRONOMY

1.8C10.10 COSMOLOGY:MODEL OF THE UNIVERSE    Use Hoberman Sphere to illustrate expansion of the universe. Junction (galaxies) remain same size while space between expands.

2. Meteorite samples available.

3. Sunset simulation.See optics section.

4. Schmidt-Cassegrain, Newtonian and refractor telescopes available. Yoke/Fork Equatorial, Dobsonian Alt-Azimuth & German Equatorial mounts available.

5.  8B10.30 STELLAR: SUNSPOT SIMULATION  Place clear  lightbulb on overhead projector. Connect to variac. Adjust variac until glows ( ~25 on variac scale). The filament image will be projected by projector. Turn on projector. The filament will now look dark comapred to bright background.


                                         NEW SECTION ADDED TO DEMONSTRATION WEB SITE

                                                                 MODERN PHYSICS

The following demonstrations are now available in the Modern Physics category.

Quantum Effects: Photoelectric effect using phototube, photelectric effect using solar cell, vibrating ring to similate electron orbit
Atomic Physics: Assorted element emission lines, sodium emission lines, molecular emission lines (carbon dioxide & water)
Nuclear Physics: Radioactive sources, shielding, probability,cosmic rays
Relativity: Coil & Magnet, Frames of Reference

New(not on web site): broadband absorption spectra, half-life apparatus, view three spectra at same time (sodium, continuous,emission), CD with muon decay movie

A NEW PHYSICS MYSTERY  A circuit consisting of two resistors (different values) and two pieces of wire is placed around a coil like the one used for jumping ring. A voltmeter is connected to the midpoint of the two wires and placed on the left. A second voltmeter is also connected to the midpoint of the wires and placed on the right. The coil is connected to an ac power source. The two meters will show very different voltages. This raises questions about the concept of potential/potential energy in an electrical circuit. It also raises a practical problem if you are measuring voltage where induced EMFs are present. This circuit can also be used as a simulation of quantum superposition. It acts like it is two circuits at once. It could also be used as example of symmetry breaking or parity non-conservation.

See other Physics Mysteries after Physics Toys below.

                                                                     PHYSICS TOYS

1. Mutant flying pig: Eats batteries. Not sure why Arbor Scientific is selling this. Useful as visual aid in discussing circular motion in Physics 1000, Astronomy or Physics 1500.

2. Light up gyroscope: Gyroscope lights up as it spins. Use in connection with angular momentum.

3. Hall hockey pucks: If you have a small class or have large space like Parker 307, put these on the floor and use for 2 dimensional collisions. Float on air cushion. Can be kicked. Advance notice needed to charge up batteries.

4. Smoke ring blower: Gun like device blows smoke rings. Produce vortex like hurricane or tornado.

5. Hoberman sphere: Illustrate expansion of the universe. Junction (galaxies) remain same size while space between expands.

6. Magnetized spheres: Use to illustrate nuclear reactions for light elements. Strong nuclear force simulated by magnetism.

7. Doppler sphere: For safety put buzzer in Nerf sphere and swing around to demonstrate Doppler shift.

8. Yo-yo: Illustrate Potential energy being transformed to kinetic energy and vice versa.

9. Sound sticks: Moving object in tube produces sound whose loudness varies as movement of object causes length of vibrating air column to go in and out of resonance.

10. Colliding balls: Put small piece of paper on one metal ball. Roll other ball so its hit first. Some of the kinetic energy will produce enough heat to burn hole in paper. If you sniff it you can tell hole was burned not torn.

11. Bounce/No Bounce: Balls look the same. One bounces. One does not. Use when talking about coefficient of restitution or energy conversion (PE>KE> heat and sound).

12. Ping-Pong glow balls: Touch metal contacts. Ball glows and makes sound. Use in connection with resistance and electrical safety.

 


                                                                  PHYSICS MYSTERIES

Physics Mystery #1. New device for discussing momentum conservation in collisions. If sharp point hits board it will wobble but not fall over. If the sharp point is removed so rubber ball hits board  it is knocked over easily. Why does it fall over even though moving object  has less mass hence less momentum?

Physics Mystery #2 DC CIRCUITS (5F20.55)  Put a light bulb in series with 2 bulbs in parallel. Predict what you think will happen. Try to explain what actually happens.  Use to talk about series and parallel circuits and temperature effect on resistance. 

Physics Mystery #3. Two bar magnets that arrived in the same box show north attracting north and south attracting south. Isn't the rule unlike attract and like repel for both charges and poles? Talk about the double standard for labeling poles N or S.
Are you a geologist or physicist?

Physics Mystery #4  Shine a laser along the axis of a cylinder filled with corn syrup. Put a piece of polaroid between laser and cylinder. At one orientation of polarizer the part of the beam farthest from laser will appear very dim. At another orientation the part of the beam nearest the laser will appear very dim. The answer to what is happening involves polarization, optical activity and scattering.

Physics Mystery #5. How can a strong magnet pick up paper? Try using some US currency. There is enough iron in the ink for some of the stronger magnets in the Demo Room to lift the paper.

Physics Mystery #6  How can a hose blowing air out suspend a ball in the air even when tilted at a 45 deg angle? What provides the upward force to overcome gravity? Bernoulli Knows.

Physics Mystery #7  Reverse Magic Instead of making something dissappear you make something appear. Show audience cylinder is empty. Show illuminated platform is empty. Put cylinder on platform. A small car appears inside. Actually the holographic image appears if the cylinder is illuminated with sodium lamp. Determine which end of cylinder is which before trying. No image if cylinder upside down. Could do this deliberately as comical touch.

Physics Mystery #8 Colliding balls revisited. Place the 2 identical spheres on one side of small spherical magnet. Roll slowly or tilt ruler slightly so larger shiny sphere hits spherical magnet on other side. Although one ball will come off on the other side as expected it will be moving surprisingly fast. Are momentum and energy not conserved? You would expect ball to move slower due to kinetic energy being tranformed into other forms of energy.

Physics Mystery #9. Magnetic Grapes?  Put a grape on the ends of a drinking straw. Balance it on the end of a needle. If you bring an electrically charged rod near a grape it will be attracted. If you bring a strong magnet near the grape it will be repelled. Use to demonstrate diamagnetism.

Physics Mystery #10. Put ice cubes on two near identical blocks. One will melt much faster. Talk about Q=mc(delta T), Q=mL, and conductivity. One block is aluminum painted black to look like other material. Other material has low heat conductivity.