Chemistry/Typical Magic Show

Equipment

 * big stand with clamps and tubing
 * 2 L beaker
 * big glass funnel
 * small step–ladder

Solutions
3–Bottle A (Dilute 4.0 g Na2CO3 to 500 mL, add 0.2 g luminol and stir to dissolve. Add 24.0 g NaHCO3, 0.5 g (NH4)2CO3•H2O and 0.4 g CuSO4•5H2O and dissolve.  Dilute to 1 L.) 3–Bottle B (50 mL of 3% H2O2 diluted to 1 L)

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To Perform
Pour equal amounts of bottles A and B into funnel, with lights off (adjust pouring rate to get maximum glow)
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What is Happening?
Luminol is a special molecule which reacts to form a product having electrons in a highly excited energy level. As the molecule loses energy and its electrons fall down to a lower energy state, the energy lost is in the form of light.

Equipment

 * Candle taped to the end of a meter stick
 * matches
 * spray bottle

Chemicals
Make a mixture of 100 mL of ethanol, 15 mL of water and about 3 g of lithium chloride. Shake to dissolve as much lithium chloride as possible.

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To perform
Put about 50 mL of ethanol in the spray bottle. Hold a lit candle at arm’s length. Hold the spray bottle about 4–6 inches from the candle and quickly spray ethanol through the flame. This should produce a nice little fireball that lasts for a second.
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Equipment

 * 500 mL graduated cylinder
 * gloves
 * sponges for clean up

Solutions

 * 300 mL of 30% hydrogen peroxide
 * 45 mL of dish washing detergent
 * 30 g of potassium iodide

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To Perform
WEAR GLOVES! Pour about 100 mL of hydrogen peroxide into the graduated cylinder, add about 15 mL of detergent and add about 10 g of sodium iodide. Huge yellow worm springs out of cylinder!
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What is happening?
The hydrogen peroxide oxidizes the iodide ion to iodine, while simultaneously releasing oxygen gas. The gas is trapped in the detergent, creating a foam.

Equipment

 * Vacuum pump
 * bell jar with bell jar base
 * can of shaving cream
 * large petri plate supported over three pieces of wood (to avoid plugging of air exit hole)
 * vacuum hose.

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To perform
Put a generous daub of shaving cream in petri plate, put bell jar over plate base, turn stopcock to off, connect vacuum pump to bell at stopcock and turn on pump. Open stopcock and watch shaving cream swell up and completely fill inside.
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What is happening?
The shaving cream is full of gas bubbles in equilibrium with the gas pressure of the atmosphere pushing down on the bubbles. When the air is removed, the bubbles expand.

Equipment

 * 4–400 mL beakers

Solutions

 * mercuric nitrate = 6.0 g/L
 * potassium iodide = 15.0 g/L

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To perform
Pour about 50 mL of mercuric nitrate into a 400 mL beaker. Then pour about 150 mL of potassium iodide solution into a beaker and from it pour about 25 mL, while swirling, into the mercuric nitrate jar; the mixture turns orange. Ask if anyone wants a nice glass of orange juice, made with the best mercury compounds available – keep the beaker containing the potassium iodide in your hand, in visible view. When no-one takes up the offer, shrug and tell the audience that you will get rid of the orange juice – quickly pour the last 125 mL of the potassium iodide into the “orange juice”, with constant swirling – the colour disappears.
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What is Happening?
When iodide ion is added to mercury(II) ion, a precipitate of solid HgI2(s) is formed. When more iodide ions are added, the colourless ion is formed (and the solid dissolves).

Equipment

 * 8 candles with holders
 * 5 stirring rods

Chemicals
very small bottle of concentrated sulphuric acid
 * GENTLY mix a pea-sized amount of potassium chlorate with an equal amount of sugar. DANGER: NEVER GRIND ANYTHING WITH POTASSIUM CHLORATE. IT IS A POWERFUL OXIDIZING AGENT AND MAY EXPLODE.  GENTLY MIX THE SUGAR AND POTASSIUM CHLORATE BY PLACING THEM IN THE MIDDLE OF A SHEET OF PAPER AND ROCKING THEM BACK AND FORTH.

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To Perform
Make a 1/4 inch depression in the top of the candle, next to the wick and gently fill the depression with the sugar/potassium chlorate mixture. Carefully touch the top of the mixture at the top of the candle with a long stirring rod having a drop of sulphuric acid on the top. In a few seconds the flame will be produced and the candle will appear to light.
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Equipment

 * Part A: small glass (with even lip)
 * 6–pieces of cardboard (About 15 cm x 15 cm)


 * Part B: styrofoam cup
 * 15 cm square piece of cardboard having “Do not remove this cardboard” written on both sides
 * 400 mL beaker

Chemicals

 * jug of water
 * sodium polyacrylate powder

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To Perform
Part A:Fill the glass 3/4 full of water, place the cardboard over the end of the glass and invert the glass. Let go of the cardboard and the water stays in the glass.

Part B:Put some sodium polyacrylate powder into a styrofoam cup (ahead of time, unseen). Have a student hold the cup in the air with both hands. Then pour water out of the pitcher into the cup and put the second piece of cardboard over the mouth of the cup. While the student is still holding the cup, turn it upside down over the student’s head and lower the cup onto the student’s head. Then, pull the piece of cardboard out and have the student read the card. Finally, lift the cup up off the student’s head, showing that no water comes out.
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What is Happening?
Part A: As the water tries to come down out of the glass, the pressure inside the cup is lowered. The greater pressure of the atmosphere outside then pushes the cardboard firmly against the rim of the glass.

Part B: The sodium polyacrylamide quickly forms a gel when water is added.

Equipment

 * 250 mL acetone in juice bottle, with small label
 * 500 mL distilled water in juice bottle, with small label
 * 4 new styrofoam cups

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To perform
Pour distilled water into cup and drink. Ask if someone else wants a “nice strong drink” and quickly pour half a cupful of acetone (HOLD IT OVER AN ORANGE BUCKET WHEN OFFERING IT TO SOMEONE – you have 3 seconds before the bottom drops out!)
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Equipment

 * 2 L beaker
 * jug of water

Chemicals

 * Lycopodium powder in a test tube

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To Perform
Pour test tube of lycopodium powder onto the surface of the beaker of water. Slowly push hand below the surface of the water and then bring your hand back out. The hand will be dry.
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What is Happening?
Lycopodium powder is “hydrophobic” (it repels water, similar to oil). When a hand is pushed down into the water, a thin layer of air is trapped between the hand and the powder. Since the powder repels water, the hand remains dry. The beautiful silvery colour of the water against the hand is actually the reflection of light off the water–air interface. (This might be similar to how a fish sees the sky.)

Equipment

 * Smoke cannon
 * paper towel
 * extra elastics (large and long)

Solutions

 * Concentrated hydrochloric acid (in squirt bottle)
 * Concentrated ammonia (in squirt bottle)

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To Perform
Place some ammonia and hydrochloric acid at different places on paper towel inside cannon. Pull back handle and fire.
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What is Happening?
Ammonia and hydrochloric acid give off fumes which combine to form a “smoke” made of solid ammonium chloride. As the air rushes out of the mouth of the cannon, a region of partial vacuum forms in the region behind the onward–rushing air. This partial vacuum pulls in the surrounding air and forms a doughnut–like “vortex” which is similar to a miniature “tornado”.

Equipment

 * 500 mL florence flask with stopper to fit

Chemicals

 * 300 mL distilled water
 * 8 g potassium hydroxide
 * 10 g dextrose
 * 6–8 drops of methylene blue indicator (indicator solution prepared by dissolving 0.20 g methylene blue in 100 mL water)

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To perform
Dissolve 8 g KOH in 300 mL distilled water in 500 mL florence flask. Just prior to doing the demonstration, dissolve 10 g dextrose in the KOH solution and then add 6–8 drops of methylene blue solution. Swirl the flask and allow it to sit undisturbed until it becomes colourless (about one minute).

To do the demonstration, give the flask a quick shake or two. The blue colour appears 	again and then slowly fades. This process can be repeated many times.
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What is Happening?
The oxygen present in the flask oxidizes the methylene blue dye to its blue form. The basic conditions cause the dextrose to reduce the methylene blue dye to its colourless form. Shaking the flask reintroduces more oxygen into the solution and re-oxidizes the methylene blue to its blue form, continuing the cycle until the oxygen in the flask is used up.

Equipment

 * 6–250 mL flasks, with stoppers
 * 2–yellow tote trays
 * 600 mL beaker (to contain scrapings)
 * spatula

Solutions
In a clean 250 mL flask, dissolve 130 g of sodium acetate in 100 mL distilled water (with heating). Stopper and let cool COMPLETELY UNDISTURBED. Prepare 6 such flasks. Also have on hand a small beaker with a gram or so of sodium acetate crystals.

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To perform
Carefully move the flask to where the demonstration will take place – DON’T JAR IT! Unstopper the flask and, while holding the flask up for the audience to see, add a couple of crystals of sodium acetate.
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What is Happening?
Sodium acetate has a peculiar crystal structure. When this compound is melted, it is difficult for the molecules to “remember” how to form a crystal again. The solution is “supersaturated” and when a crystal of sodium acetate is added to the liquified material, the sodium acetate suddenly “remembers” how to crystallize and BINGO!

Equipment

 * Old neon sign from sign company specializing in neon signs
 * stands and clamps for neon lights
 * fluorescent tube
 * Tesla coil

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To perform
Touch one end of the neon light with an operating Tesla coil. A bright red light emission from neon is seen near the metal electrodes; the colour then changes depending on the coating inside the glass tube. (Argon lights give a blue emission.)

Have one person hold the fluorescent tube and another person touch the tesla coil to the tube, lighting up the tube.
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Equipment

 * 3–25 mL graduated cylinders (labelled BW–A, BW–B, BW–C)
 * 1–100 mL graduated cylinder (labelled BW)
 * 3–250 mL beakers

Solutions

 * A = 15.0 g potassium iodate / L
 * B = 3.0 g mercuric nitrate / L
 * C =15.0 g sodium metabisulphite + 4.0 g starch + 1.0 g salicylic acid + 10.0 mL ethanol / L

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To perform
Add 20 mL of A and 15 mL of B to 100 mL water and stir well for 5 s. Then add 20 mL of C to the mixture and stir well for 5 seconds.
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What is Happening?
A reaction quickly produces orange–coloured mercury(II) iodide, but a second reaction starts to use up the mercury(II) iodide and produce iodine molecules. A third reaction is using up the iodine molecules as fast as they are made, but when the third reactant is finally used up the iodine being produced is available to react with a starch–salicylic acid mixture to produce a black colour.

Equipment

 * candle and matches

Chemicals

 * pieces of guncotton

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To Perform
throw the guncotton into a flame
 * }

What is Happening?
The cellulose in the cotton has been treated with nitric acid to make nitrocellulose, which burns rapidly and leaves no residue.

Equipment

 * 500 mL separatory funnel
 * 2–400 mL beaker (one to contain HCl and one to catch liquid from separatory funnel)
 * 1 L beaker to hold ice for cooling HCl
 * distillation apparatus (optional)
 * magnetic stirrer, with stir bar
 * 500 mL graduated cylinder or (600 mL beaker and 250 mL graduated cylinder)
 * 10 mL graduated cylinder
 * dropping pipet

Chemicals

 * 250 mL 70% ethanol (175 mL of ethanol + 75 mL of water)
 * 1 mL of tert–butyl chloride
 * 4 mL of universal indicator
 * a few millilitres of 1 M NaOH

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To perform
Into either a 500 mL graduated cylinder or a 600 mL beaker place 250 mL of distilled water and 250 mL of isopropyl alcohol. Place the container on a magnetic stirrer and begin stirring. Add 1 mL of tert-butyl chloride and stir for another 15 seconds, add 4 mL of universal indicator and stir for another 15 seconds. Finally, add a few drops of 1 M NaoH and continue stirring. The initial blue colour will turn to green, orange and finally red. The process can be repeated by adding some additional NaOH to the reaction mixture.
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Equipment

 * Magnetic stirrer, with stirring bar
 * 2 L beaker
 * large bag of polystyrene packing chips

Chemicals

 * 400 mL of acetone

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To perform
Rapidly stir 400 mL of acetone in the 2 L beaker. As the foam chips are added, they rapidly dissolve. Students are usually amazed at the large volume of chips that can be reduced to a substantially smaller volume.
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Equipment
Magnetic stirrer, stir bar, 500 mL beaker, 3–100 mL graduated cylinders, piece of white paper to serve as a backdrop, scotch tape.

Solutions

 * Solution A = 120 mL 30% hydrogen peroxide added to 300 mL distilled water
 * Solution B = 12.9 g potassium iodate and 1.5 mL concentrated sulphuric acid added to 300 mL distilled water
 * Solution C = Make a paste of 0.15 g soluble starch in some hot water and add, with stirring, to 500 mL water. Then add 7.8 g malonic acid and 1.7 g MnSO4•H2O.

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To Perform
Put 100 mL solution A in 600 mL beaker and sit on magnetic stirrer at lowest setting. Then add 100 mL solution B and then 100 mL solution C.
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Equipment

 * pile of ceramic pads, dustpan, brush, squeeze bottle of water, 2 spatulas

Chemicals

 * 6 sets of – vial containing 4.0 g powdered zinc
 * vial containing 4.0 g NH4NO3 + 1.0 g NH4Cl + 0.5 g Ba(NO3)2

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To Perform
Pour contents of one of each type of the 2 vials onto middle of ceramic pad. Mix very carefully with spatula. At arms length, squeeze a few drops of water on the mixture. Care: flares up quickly!
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What is Happening?
Powdered zinc has an enormous surface area. When water is added, the zinc is ionized and creates a substantial amount of heat in the process. The ammonium nitrate is a strong oxidizing agent which accelerates the reaction and eventually causes the zinc to burn in air.

Equipment

 * lycopodium exploder (see reference or below)
 * small birthday candle
 * match
 * rubber tubing: 3/8” OD, 5 feet
 * wide stem Beral pipette
 * sponge (for clean up)

Chemicals

 * Bottle of lycopodium powder

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To perform
Insert the tubing into the bottom of the plastic bottle. Arrange the candle so the wick is in the centre of the bottle. Use the pipette to place 3–5 “loads” of lycopodium into the bottle end of the tubing. Make sure the end of the tubing is aimed at the end of the candle and light the candle. Turn off the room lights: take a large breath and blow into the other end of the tubing. A huge fireball erupts above the bottle.
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