All Experiments
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All Experiments

All Experiments

Listed below are all the experiments for this topic.

• Absorbing radiant energy with different surfaces
• Absorption lines in the spectrum of sunlight
• Absorption spectrum of sodium
• Accelerating kilogram masses
• A CD (or gramophone record) as a grating
• Acoustic interferometer
• AC power line at high voltage
• Action and reaction: trolleys
• Action and reaction with a metre rule
• Action and reaction with a metre rule
• Adding mass to a moving system
• Additive colour mixing
• A gravitational store of energy
• Air expanding at constant pressure: Charles’ Law
• Alpha particle scattering
• Alpha radiation: range and stopping
• A magnet moving near a coil on a C-core
• A model buzzer
• A model electric bell
• A model galvanometer
• A model hot-wire ammeter
• A model moving-iron meter
• A model of growing crystals
• A model of Millikan’s experiment
• A model of vibrating atoms in a solid
• A model transformer
• An application of Newton's rings experiment
• An eccentric scheme for the Sun
• An electric motor used as a generator
• An epicycle system for planets
• An example of a constant, moving force
• An introduction to simple harmonic motion
• Apparent weightlessness
• Applications of the conservation of momentum
• A quick comparison of densities
• Aristarchus’ solar system
• A see-saw weighing device
• A simple balance 1
• A simple balance 2
• A simple celestial sphere
• A simple mercury barometer
• A simple spectrum
• A steam engine
• A step-up transformer
• Atmospheric pressure and a mercury column
• Atmospheric pressure shown using a mercury-filled manometer
• A toy car with two motions
• A transistor as a current amplifier
• A trolley started and stopped by catapults
• Attenuation of radiation
• Balancing a beam
• Balancing forces
• Bernoulli effect demonstration
• Bernoulli experiments with sheets of paper
• Beta radiation: deflection in a magnetic field
• Beta radiation: range and stopping
• Beyond the visible spectrum
• Bicycle dynamo
• Bicycle dynamo and oscilloscope
• Boyle's law
• Brandy tears
• Breaking a magnet
• Broomstick pendulum, sinusoidal motion
• Brownian motion in a smoke cell (with video clip)
• Brownian motion of carbon particles in water
• Building a reaction tester
• Bungee challenge
• Butthead
• Calibrate a forcemeter by pulling a student
• Calibrate a forcemeter by pulling a trolley
• Calibrating a voltmeter
• Capillary action
• capital letters
• Catapult magnetic field
• Centimetre waves
• centripetal force kit
• Change in volume from a liquid to a gas for nitrogen
• Change of volume on vaporization
• Change of volume: petrol to petrol vapour
• Change of volume: water to water vapour
• Change of volume with nitrogen
• Charging by electrostatic induction
• Circuits from circuit diagrams
• Circuit with extra resistance
• Clearing smoke
• Cleavage of large crystals
• Climbing stairs
• Coarse diffraction grating
• Collisions between balls
• Collisions on an air-track
• Collisions with coins
• Collisions with electrostatic forces
• Comparing rms value and peak value of AC
• Comparing short cameras and long cameras
• Comparing the powers of electric motors 1
• Comparing the powers of electric motors 2
• Comparing the powers of lamps
• Comparing the thermal conductivities of different materials
• Comparison of two kilogram masses
• Compensating for friction
• Compound microscope
• Conduction in a gas
• Conduction of liquids
• Conductivity of germanium
• Constant and varying forces between trucks
• Convection currents in a beaker of liquid
• Convection in a Bunsen flame
• Convection in a test-tube of liquid
• Copernicus explains the motion of planets
• Copper plating various metal objects
• Copper wire, PVC covered, 150 cm with bare ends
• CO₂ puck on a glass plate
• Counting matches with an EHT supply
• Counting matches with a Van de Graaff generator
• Counting spoonfuls of salt
• Cracking glass
• Cracking glass - additional demonstrations
• Crossed wires - electrical fault-finding
• Crunchie bones
• Crushing an evacuated container
• Crystal models made of marbles
• Crystals dissolving in water
• Currents and conductors
• Curved ray of light
• Cutting a magnetic field with a wire
• Cylindrical mirror, aberration and caustic curve
• Datalogging magnetic induction
• Datalogging S.H.M. of a mass on a spring
• Defining the 'joule'
• Deflecting an electron beam
• Demonstrating weightlessness
• Demonstration electroscope
• Demonstration spectrum
• Dependence of size on method of measurement
• Depth of field for a camera
• Diameter of the Moon
• Different densities of gases
• Diffraction at narrow openings
• Diffraction at wide openings
• Diffraction of a plane wave by multiple gaps
• Diffraction patterns using sieves
• Diffusion cloud chamber
• Diffusion of ammonia and hydrogen chloride gas
• Diffusion of bromine vapour
• Diffusion of copper sulfate crystals in water
• Diffusion of copper sulfate solution in water
• Diffusion of hydrogen into air
• Diffusion of nitrogen dioxide into air
• Diffusion through a porous pot
• Discussion of pressure
• Display of cloud chamber photographs
• Distance to the Sun
• Distinguishing between velocity and acceleration
• Drawing ellipses to represent orbits
• Earthquakes in the laboratory
• Eclipses
• Effect of air pressure
• Effect of a pump
• Egg and sheet
• Elastic collision of trolleys
• Elastic collisions with bodies of equal mass
• Electrical measurement of velocity of a large trolley motion
• Electric charge using capacitors
• Electric fields
• Electrolysis of copper sulfate solution
• Electrolysis of water
• Electrolysis of water and the concept of charge
• Electromagnetic braking in a copper pipe
• Electromagnets: field pattern
• Electromagnets: forces
• Electron deflection tube: straight line streams
• Electron deflection tube: using an electric field
• Electron diffraction
• Electrostatic model of alpha particle scattering
• Elliptical reflector
• Energy carried by a moving trolley
• Energy carried by an electric current
• Energy stores and carriers
• Estimate of acceleration due to gravity using pulsed water drops
• Estimating the size of a molecule using an oil film
• Estimating the size of the Earth
• Estimating wavelength, frequency, and velocity of ripples
• Eudoxus' system
• Evacuating a bottle
• Examination of boiling
• Examples of change of phase
• Examples of simple harmonic motion
• Examples of solids, liquids and gases
• Expanding liquids
• Expansion cloud chamber
• Expansion of a gas at constant pressure
• Expansion of a solid rod
• Expansion of water on freezing
• Experimental test of F = mv²/R
• Experiments with a fan of rays
• Experiments with a single ray
• Experiments with a Van de Graaff generator
• Experiments with magnets
• Experiments with rays of light
• Experiments with switches
• Explaining elastic and inelastic collisions
• Explosion of two trolleys
• Factors affecting the speed of sound
• Falling objects
• Falling through a high viscosity liquid
• Falling through air
• Falling through water
• Faraday's law
• Faraday's motor
• Feeling a force of 10 N
• Feeling the 'springiness' of air
• Filling balloons
• Finding average acceleration with a ticker-timer
• Fine beam tube
• Fine Beam Tube: a naked oscilloscope
• Fine cloth as a grating
• Flask model of the Pythagorean system
• Fleming's left hand rule (using the Earth's magnetic field)
• Flowing fluids can become charged
• Force between electromagnets
• Force of impact on a floor
• Force on a wire carrying a current in a magnetic field
• Forces due to electric charges
• Forces in an electrostatic field
• Force used to kick a football
• Fractional horse-power motor
• Frequency of a ticker-timer
• Friction between solid surfaces
• From galvanometer to ammeter
• From galvanometer to voltmeter
• Further electrostatic experiments
• Further experiments on radiation
• Further refraction demonstrations
• Further test of mv²/R
• Galileo's pin and pendulum
• Galileo's rolling ball
• Gamma radiation: inverse square law
• Gamma radiation: range and stopping
• Gas pressure: forces required to compress and expand
• Gas pressure rises with temperature
• Getting to know the joule and the watt
• Giant model of a magnet
• Gold leaf electroscope
• Gravitational model of alpha particle scattering
• Growing a crystal of alum or copper sulfate
• Guinea and feather
• Hammering lead to warm it up
• Handling crystals
• Hardboard piece to take plotting compass
• Head on collision between trolleys with magnets attached
• Hearing a laser beam
• Heating and cooling curves
• Heating effect of a current
• Herschel’s infra-red experiment
• Home-made springs
• How does the world look without glasses?
• How fuses work
• How images form
• How to make a comet
• Human energy - food and exercise
• Identifying three types of ionizing radiation
• Illustration of an elliptical orbit
• Illustration of oil spreading
• Image formation with a lens
• Increasing a gravitational store
• Independence of vertical and horizontal motions
• Inelastic collision of trolleys
• Inertia on a low friction surface
• Inertia with pendulums
• Instantaneous and average velocities
• Interference of light through two narrow holes
• Interference of water waves from two gaps
• Interference using centimetre waves
• Interference with air wedge
• Interference with plastic wave model
• Interference with two sources, using fingers
• Interference with two sources, using vibrators
• Internal resistance of a potato cell
• Internal resistance of a shoe box cell
• Introducing circular motion
• Introducing the oil film experiment
• Introducing waves
• Introduction to copper plating
• Introduction to electric forces
• Introduction to forcemeters
• Introduction to oscillations
• Introduction to statistics tally
• 'Inverse explosion' with trolleys
• Investigating a mass-on-spring oscillator
• Investigating energy transfers in a pendulum
• Investigating free fall with a light gate
• Investigating light intensity from a lamp
• Investigating momentum during collisions
• Investigating motion on a sloping surface
• Investigating Newton's second law of motion
• Investigating series and parallel circuits
• Investigating simple steel springs
• Investigating the current around a circuit
• Investigating the pressure of a water column
• Investigating the resistance of wires
• Investigating the spectrum with an electronic detector
• Investigating the time of oscillation of a pendulum
• Investigation of a bottle labelled ‘vacuum’
• Investigation of a simple pendulum
• Ions in a flame
• Ions produced by a flame carry a current
• Ions produced by radiation carry a current
• Is the ring magnetised?
• I/V characteristic of a carbon resistor
• I/V characteristic of a filament lamp
• I/V characteristic of a semiconductor diode
• Jet of steam from a boiling flask
• Jobs needing food or fuel
• Kepler's Second Law on ice
• Kepler's Second Law using a centripetal force kit
• Kepler's Second Law using a dry ice puck
• Kepler’s Second Law using the rotation of a stool
• Kepler's Second Law with a whirling bung
• Kilogram Masses, 2, made of same substance and with same shape
• Kinetic theory model for a gas
• Kinetic theory: two-dimensional model
• Lamp brightness comparison
• Lamp comparison
• Lamps in parallel
• Larger kinetic model to illustrate Boyle's law
• Large trolley investigations of acceleration
• Law of reflection
• Law of refraction
• Lead tree
• Learning to use voltmeters
• Levers and pulleys multiply force but not energy
• Looking at crystals
• Looping the loop
• Magnet and coil
• Magnetic field due to a coil carrying a current
• Magnetic field due to a long close-wound coil
• Magnetic field due to an electric current in a wire
• Magnetic field inside an open coil
• Magnetic fields due to arrangements of magnets
• Magnetic model of alpha particle scattering
• Magnetic shielding
• Making a cloud by expansion
• Making a microbalance
• Making an electric arc work from the mains
• Making a permanent magnet
• Making a photo to take home
• Making a telescope
• Making your own relay
• Maltese cross: casting shadows
• Marching model of refraction
• Massive beam and anvil to show pressure exerted by a stream of balls
• Massive pendulum
• Mean free path of marble in a tray
• Measurement of acceleration using light gates
• Measurement of g using an electronic timer
• Measuring and weighing solid blocks
• Measuring gas pressure using manometers
• Measuring e/m
• Measuring lengths in centimetres
• Measuring lung pressure
• Measuring paper
• Measuring resistance with a voltmeter and an ammeter
• Measuring the average density of a student
• Measuring the density of air 1
• Measuring the density of air 2
• Measuring the density of air 3
• Measuring the density of liquids
• Measuring the density of regular solid shapes
• Measuring the density of water 1
• Measuring the density of water 2
• Measuring the gas supply pressure
• Measuring the half-life of protactinium
• Measuring the power of a lamp
• Measuring the power of a motor
• Measuring the radius of a marble
• Measuring thermal energy
• Measuring the speed of sound 2
• Measuring the speed of sound 3
• Measuring the speed of sound using echoes
• Measuring the thickness of a coin
• Measuring the thickness of aluminium leaf
• Measuring the wavelength of light
• Measuring time intervals
• Melde's experiment
• Metre rule with cm and mm markings
• Millikan's method for money
• Mixing hot and cold water
• Model CD scanner
• Model DC power line
• Model eye demonstration with flask
• Model eye with a goldfish bowl
• Modelling a resistive survey
• Modelling for Brownian motion
• Modelling precession of the equinoxes
• Model loudspeaker
• Model of a camera
• Model of a microscope using a car lamp
• Model of a microscope with ray streaks
• Model of a solid using students
• Model of a telescope with ray streaks
• Model of expanding liquids and gases
• Model of ions in motion
• Model of planetary path
• Model of the celestial sphere
• Model of the early Greek scheme
• Model of the oblate Earth
• Model of train track signalling
• Model showing atmospheric thinning higher up
• Model to illustrate precession of the Earth
• Momentum interchanges with other objects
• More inertia experiments
• More surface tension effects
• Motion of a ball rolling down a plank
• Moving an electromagnet
• Moving an object across the table
• Moving charges are an electric current
• Moving coil meter
• Moving energy from one thing to another 1
• Moving energy from one thing to another 2
• Multiflash photographs of accelerated CO₂ pucks
• Multiflash photographs of free fall
• Multiflash photographs of motion down a slope
• Multiflash photographs of projectiles
• Musical frequencies shown on a C.R.O.
• Music from standing waves: monochord
• Newton's first law
• Newton’s Third Law
• Non-uniform acceleration with a ticker-timer
• Observing the motion of the Sun
• Observing the night sky
• Oersted's experiment
• Ohm's law
• Ohm's law with alternating current
• Ohm's law without a voltmeter
• Optical illusion with concave mirror
• Oscilloscope and alternating voltage from transformer
• Particle model of reflection
• Penny on a turntable
• Perrin tube – sign of electron charge
• Photographing the night sky
• Photograph of marbles in motion
• Physicists at play
• Pick and mix
• Pinhole camera and lens camera
• Planetarium model
• Planetary paths
• Play with magnets
• Polystyrene sphere crystal models
• Potential difference and e.m.f.
• Pouring particles
• Power cycling up a hill
• Precession
• Precession of the equinoxes
• Preparation for Millikan’s experiment (dancing men)
• Pressure and force
• Pressure exerted by a stream of balls
• Pressure of air at constant volume
• Problem circuit
• Projection of spectrum with diffraction gratings
• Pulses and continuous waves with a Slinky spring
• Pushes, pulls and muscles
• Pythagorean model of the Universe
• Race time measurement
• Radiation from black and shiny surfaces
• Radiation from Bunsen flames
• Random walk experiment 1
• Random walk experiment 2
• Ray model of telescope with field lens
• Ray of light in water
• Real and virtual images in a smoke box
• Red-hot heater and curved mirrors
• Reflecting a ray of light and a rubber ball
• Reflection at a parabolic barrier
• Reflection of a circular pulse by a barrier
• Reflection of a straight pulse by a barrier
• Reflection of ripples at a circular barrier
• Refraction in a tank of water
• Refraction of particles and of waves
• Refraction of ripples entering shallow water
• Relationship between volts and amps for electrolytes
• Relationships between acceleration, force and mass
• Retinal shadow
• Retinal shadow using a model eye
• Ring of standing waves
• Seeing sound waves
• Series and branching circuits
• Shadows and rays on a screen
• Shift a joule
• S.H.M. and circular motion
• S.H.M. on a rope
• S.H.M. with a cantilever
• Showing that a spark can pass through air
• Simple circular pulses in ripple tanks
• Simple electric circuits
• Simple electromagnet
• Simple kinetic energy transfers
• Simple model of exponential decay
• Simple molecular model of different states of matter
• Simple motion experiments with a datalogger
• Simple spectrum of sunlight
• Simple straight pulses
• Simplification of interference at air wedge
• Skateboard forces
• Sketching a satellite orbit and predicting its period
• Slow AC with a capacitor
• Slow AC with a capacitor and an inductor
• Slow AC with a low frequency generator and a voltmeter
• Slow AC with a low frequency generator and oscilloscope
• Slow AC with an ohmic resistor
• Soap film
• Solid carbon dioxide turning into a gas
• Sound and light: energy carriers
• Sound waves
• Specific thermal capacity of aluminium
• Specific thermal capacity of aluminium more accurately
• Spectra
• Spectra formed by gratings
• Speed of a rifle pellet measured with a scaler or timer
• Spinning demonstration with V-channel
• Standing waves
• Standing waves along trolleys
• Stationary waves in an air column
• Stretched elastic band: an elastic store of energy
• Stretching and compressing materials
• Stretching copper wire (qualitative)
• Stretching copper wire (quantitative)
• Stretching rubber
• Stretchy sweets
• Stroboscope: introduction
• Student power
• Studying a commercial relay
• Study of the diffraction of light at narrow openings
• Surface tension
• Surface tension: aniline dripping in water
• Switching an electromagnet
• Switching on a lamp
• Symbol Tests
• Telescope magnification
• Temperature change and resistance
• Testing fuses
• Testing Pop Up Windows
• Testing projectile motion with a drawn parabola
• Test of mv²/R on a turntable
• Thales' model of the Universe
• The 'apple and arrow' experiment
• The barometer
• The current balance
• The current-through-glass demonstration
• The dangers of 'static'
• The Earth's gravitational pull
• The effect of heating common salt and paraffin-wax
• The effect of temperature on a thermistor
• The effect of temperature on conductivity
• The effects of force and mass on motion
• The electric compass needle
• The electric motor
• The "electron gun" or valve diode
• The game of Sym
• The Geiger-Müller tube
• The image of a candle in a plane mirror
• The inertia balance or 'wig-wag'
• The inverse square law with light
• The lens formula
• The magnifying glass: qualitative
• The magnifying glass: quantitative
• The Moon’s distance from Earth
• The motion of the Moon around the Earth
• The motor as a dynamo
• The need for high voltage in power lines
• The power wasted inside a battery
• The range of accommodation of the eye
• Thermal expansion of air - Charles' law
• Thermal radiation from the human body
• The spark counter
• The specific thermal capacity of lead
• The speed of a rifle pellet by momentum
• The spinthariscope
• The Sun’s luminosity
• The swinging pendulum
• The velocity of a very long pendulum
• The virtual image in a plane mirror
• The voltmeter as a cell (battery) counter
• The water barometer
• The water circuit: modelling current and potential difference
• The waveform of AC on a demonstration oscilloscope
• Thin wire, strong, length 3.5m
• Three-dimensional model used to illustrate Boyle's law
• Ticker-timers for investigating speed
• Time intervals using a heavy pendulum
• Timing a trolley on a slope
• Transformer: dependence on number of turns
• Transmitting and absorbing radiant energy
• Transverse waves along a rope
• Trolley and falling mass
• Trolley collisions
• Turning effects and a clock-spring
• Two-dimensional collisions with ball bearings
• Two-dimensional diffraction grating
• Two dimensional momentum interchanges with pucks
• Understanding colours
• Understanding measuring cylinders
• Use of a voltmeter
• Using a Bourdon gauge to measure lung pressure
• Using a brick to introduce energy
• Using a CRO as a voltmeter
• Using a CRO to measure short time intervals
• Using a CRO to show acoustic waveforms
• Using a CRO to show an AC waveform
• Using a CRO to show different waveforms
• Using a CRO to show rectification by a diode
• Using ammeters
• Using an electric motor to raise a load
• Using an energymeter to measure efficiency of energy transfer
• Using an energymeter to measure power in electrical circuits
• Using a stroboscope to 'freeze' continuous ripples
• Using magnifying glasses and microscopes
• Using the telescope like an astronomer
• Using the ticker-timer to measure time
• Variable focus eye
• Variation of gas pressure with temperature
• Velocity-time graphs with a ticker-timer
• Vibrating tuning fork and rotating mirror
• Vibrations in a rubber sheet
• Vibrator to generate continuous waves
• Viewing sharp shadows
• Voltage/current relationship for a gas
• Volume change on dissolving salt in water
• Warming up a gas by speeding up its particles
• Watching crystal growth under a microscope
• Watching crystals form quickly
• Watching one ripple crossing another
• Water circuit
• Water jet through rings
• Water waves seen in section
• Waves along a line of students
• Waves with trolleys
• Weighing air
• Weighing a sample of air – a rough estimate
• Weighing liquids
• Wet paper demonstration of electrolysis
• What affects the output of a solar panel?
• What's the frequency?
• Whirling a rubber bung and letting go
• Whirling a rubber bung on a string
• ‘Wholesale’ photoelectric effect
• Why does reducing volume increase pressure?
• Working against a band brake
• Young's fringes with centimetre waves
• Young's fringes with sound waves
• Young's slits with light

Updated 11 Apr 2006

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