Particle model of matter

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Created by
Ellie Robinson

Cards (38)

  • Density
    The mass per unit volume of a material
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  • Density equation
    1. ⍴=m/v
    2. Density (kg/m³)
    3. Mass (kg)
    4. Volume ()
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  • States of matter in order of increasing density
    • Gas
    • Liquid
    • Solid
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  • Solid
    • Tightly packed in a regular arrangement
    • Particles can only vibrate on the spot
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  • Liquid
    • Close together, but with an irregular arrangement
    • They can flow over each other
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  • Gas
    • Separated, with no regular arrangement
    • Particles can move freely
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  • Mass is always conserved when a substance undergoes a change of state
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  • Change of state
    The material can return to having its previous properties if the change is reversed
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  • Chemical change

    The material cannot return to having its previous properties
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  • Sublimation
    A solid changes into a gas without passing through a liquid state
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  • Evaporation
    A liquid changes into a gas state
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  • Condensation
    A gas changes into a liquid state
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  • Water boils in an open pan
    The mass of the pan of water appears to decrease because some of the water will evaporate and turn into water vapour, leaving the pan, but the mass of the whole system remains constant
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  • Bathroom mirror mists up
    1. Hot water evaporates to form water vapour
    2. This water vapour lands on the cooler mirror
    3. The vapour condenses and returns to liquid state on the mirror's surface
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  • Internal energy of a substance
    • The energy stored by the particles
    • The sum of the total kinetic and potential energies that make up the system
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  • Heating a substance
    • Transfers energy to the substance
    • Increases the energy of the particles that make up the substance
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  • Heating a substance
    • Can raise its temperature
    • Can change the state of the substance
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  • Factors determining temperature change of a system
    • Mass of substance being heated
    • Type of material (Specific heat capacity)
    • Energy inputted into the system
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  • Equation for temperature change when a substance is heated
    • ΔE = m c Δ𝛉
    • Energy (J), Mass (kg), Specific Heat Capacity (J/kg/°C), Temperature (°C)
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  • Specific heat capacity
    The amount of energy needed to increase the temperature of 1kg of a substance by 1°C
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  • Change of state
    • The internal energy of the substance will be increased or decreased
    • The temperature of the substance will remain constant
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  • Specific latent heat
    The amount of energy needed to change the state of 1kg of a substance with no change in temperature
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  • Motion of molecules in a gas
    They are in constant random motion
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  • Equation for energy required to change state
    • Energy to change state = mass x specific latent heat
    • Energy (J), Mass (kg), Specific latent heat (J/kg)
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  • Factor affecting average kinetic energy of gas molecules
    • The temperature of the substance
    • The higher the temperature, the higher the average kinetic energy of the molecules
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  • Specific latent heat of fusion
    The energy required to change 1kg of a substance from solid state to liquid state without a change in temperature
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  • Increasing temperature of a gas held at constant volume
    Pressure of the gas will increase
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  • Specific latent heat of vaporisation
    The energy required to change 1kg of a substance from liquid state to gas state (vapour) without a change in temperature
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  • Why pressure increases as temperature increases (at constant volume)
    1. Kinetic energy of molecules increases
    2. Collisions between molecules becomes more frequent
    3. Greater rate of change of momentum
    4. Greater force and therefore pressure
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  • If gas A is at low pressure, and gas B is at high pressure

    • There are more collisions per second in gas B than in gas A
    • The rate of collisions is higher in B
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  • Force exerted by pressure of gas on container walls
    • The net force acts at right-angles to the container's surface
    • The force increases as pressure increases
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  • How increasing volume of gas results in decreased pressure
    1. Molecules become more spread out and so time between collisions increases
    2. This reduces the rate of collisions
    3. Rate of change of momentum decreases, and so force exerted on container decreases, resulting in a lower pressure
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  • For a fixed mass of gas at constant temperature, the product of pressure and volume is constant
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  • Unit for pressure
    Pascal (Pa)
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  • What increases when you do work on a gas
    • The internal energy of the gas
    • This can also lead to an increase of temperature
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  • Why temperature of air inside a bike pump increases when pumped
    1. Work is done on a gas when it is compressed
    2. Doing work on a gas increases its internal energy, so also increases the average kinetic energy of the molecules
    3. Temperature increases with an increase of average kinetic energy
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  • Unit for specific latent heat
    J/Kg
  • When the volume of gas in the syringe increases the pressure on the inside walls decreases. Why?
    there are less frequent collisions between the walls of the syringe and the particles, causing a lower total force on walls of syringe, and pressure is total force per unit are