A1 PaCKelvinSometimescalled'absolutetemperature'Areameasuredin m^2SpecificHeatCapacityHeat energyrequired to changethe temperature of1 kg of asubstance by 1degree celsiusBChange inTemperatureinverselyFor an idealgas, pressureand volumeare _________proportionalLatentheat offusionThe heat requiredto change thephase of 1 kg ofa substance fromsolid to liquid.KineticEnergyEnergyofmotionLatent heatofvaporisationThe heat requiredto change thephase of 1 kg ofa substance fromliquid to gas.A graph ofpressurevs.VolumeWork= Forcexdistance273To convertto K fromC, add______directlyFor an idealgas,temperatureand volume are_________proportional4180The specificheatcapacity ofwaterThekineticmodelall matter is made of smallparticles which are inrandom motion. By makingsimple assumptions aboutthese particles a lot aboutthe physical properties ofmatter and how it behavescan be explained.PotentialEnergyStoredenergyHeatEnergyE_hstandsforjoulesUnit ofwork2100The specificheatcapacity oficeThe latentheat offusion ofwater.PowerForceEqual toPressurex AreaConservationof EnergyEnergycannot becreated ordestroyedDEPressureForceper unitareaA graph ofpressure vstemperatureTemperatureA measure ofthe averagekineticenergy ofparticlesHeat(andsound)When energy is'lost' from asystem, it isalmost alwaystransformedinto :The latentheat ofvaporisationof waterVolumemeasuredin ml orm^3A1 PaCKelvinSometimescalled'absolutetemperature'Areameasuredin m^2SpecificHeatCapacityHeat energyrequired to changethe temperature of1 kg of asubstance by 1degree celsiusBChange inTemperatureinverselyFor an idealgas, pressureand volumeare _________proportionalLatentheat offusionThe heat requiredto change thephase of 1 kg ofa substance fromsolid to liquid.KineticEnergyEnergyofmotionLatent heatofvaporisationThe heat requiredto change thephase of 1 kg ofa substance fromliquid to gas.A graph ofpressurevs.VolumeWork= Forcexdistance273To convertto K fromC, add______directlyFor an idealgas,temperatureand volume are_________proportional4180The specificheatcapacity ofwaterThekineticmodelall matter is made of smallparticles which are inrandom motion. By makingsimple assumptions aboutthese particles a lot aboutthe physical properties ofmatter and how it behavescan be explained.PotentialEnergyStoredenergyHeatEnergyE_hstandsforjoulesUnit ofwork2100The specificheatcapacity oficeThe latentheat offusion ofwater.PowerForceEqual toPressurex AreaConservationof EnergyEnergycannot becreated ordestroyedDEPressureForceper unitareaA graph ofpressure vstemperatureTemperatureA measure ofthe averagekineticenergy ofparticlesHeat(andsound)When energy is'lost' from asystem, it isalmost alwaystransformedinto :The latentheat ofvaporisationof waterVolumemeasuredin ml orm^3

Properties of Matter Bingo - Call List

(Print) Use this randomly generated list as your call list when playing the game. There is no need to say the BINGO column name. Place some kind of mark (like an X, a checkmark, a dot, tally mark, etc) on each cell as you announce it, to keep track. You can also cut out each item, place them in a bag and pull words from the bag.


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  1. A

  2. 1 Pa

  3. C
  4. Sometimes called 'absolute temperature'
    Kelvin
  5. measured in m^2
    Area
  6. Heat energy required to change the temperature of 1 kg of a substance by 1 degree celsius
    Specific Heat Capacity

  7. B

  8. Change in Temperature
  9. For an ideal gas, pressure and volume are _________ proportional
    inversely
  10. The heat required to change the phase of 1 kg of a substance from solid to liquid.
    Latent heat of fusion
  11. Energy of motion
    Kinetic Energy
  12. The heat required to change the phase of 1 kg of a substance from liquid to gas.
    Latent heat of vaporisation
  13. A graph of pressure vs. Volume
  14. = Force x distance
    Work
  15. To convert to K from C, add ______
    273
  16. For an ideal gas, temperature and volume are _________ proportional
    directly
  17. The specific heat capacity of water
    4180
  18. all matter is made of small particles which are in random motion. By making simple assumptions about these particles a lot about the physical properties of matter and how it behaves can be explained.
    The kinetic model
  19. Stored energy
    Potential Energy
  20. E_h stands for
    Heat Energy
  21. Unit of work
    joules
  22. The specific heat capacity of ice
    2100
  23. The latent heat of fusion of water.

  24. Power
  25. Equal to Pressure x Area
    Force
  26. Energy cannot be created or destroyed
    Conservation of Energy

  27. D

  28. E
  29. Force per unit area
    Pressure
  30. A graph of pressure vs temperature
  31. A measure of the average kinetic energy of particles
    Temperature
  32. When energy is 'lost' from a system, it is almost always transformed into :
    Heat (and sound)
  33. The latent heat of vaporisation of water
  34. measured in ml or m^3
    Volume