electricity

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Created by
Elza Abbasova

Cards (29)

  • This video is about electricity
  • There are three key quantities: V, I, and R
  • Current (I)
    The rate of flow of charge particles
  • Conventional current
    Flows from positive to negative, but the actual charge carriers (electrons) move from negative to positive
  • Potential difference (V)
    The energy transferred per unit charge
  • Resistance (R)
    The ratio of potential difference across a component to the current in that component
  • Investigating component characteristics
    1. Set up simple circuit with ammeter and voltmeter
    2. Use potential divider circuit to vary current and potential difference
  • IV characteristics

    • Relationship between current (I) and potential difference (V)
    • For ohmic conductors, current is proportional to potential difference (Ohm's law)
    • For non-ohmic conductors, relationship is not linear
  • Components with different IV characteristics

    • Resistor
    • Filament lamp
    • Diode
  • Resistivity (ρ)

    Material property that determines resistance, depends on length and cross-sectional area of conductor
  • As temperature increases

    Resistance of most materials increases
  • Semiconductors
    As temperature increases, more charge carriers are liberated, making it easier for current to flow, so resistance decreases
  • Superconductors
    Below a critical temperature, resistance drops to zero
  • Kirchhoff's first law: the sum of currents into a junction equals the sum of currents out of the junction
  • EMF (ε)
    The energy transferred to the circuit per unit charge by a source like a battery
  • Around any closed loop in a circuit, the sum of the EMFs is equal to the sum of the potential differences
  • EMF
    Energy transferred to the circuit by a battery
  • Potential difference
    Work done per unit charge, energy transferred within a component
  • Around any closed loop in the circuit

    The sum of the EMFs is equal to the sum of the potential differences
  • Series circuit

    • Same current everywhere
    • Current in = current out
  • Parallel circuit

    • Current splits at a junction
    • Potential difference is the same across each branch
  • Calculating total resistance in series circuit

    Add up individual resistor values
  • Calculating total resistance in parallel circuit

    Take reciprocal of sum of reciprocals of individual resistor values
  • Power
    • Rate of energy transfer
    • P = IV
    • P = I^2R
    • P = V^2/R
  • Total energy transferred

    Power x time = IVt
  • Potential divider circuit

    • Splits potential difference between two resistors
    • Can use for sensing circuits like thermistors or LDRs
  • Internal resistance

    • Resistance within a cell or power supply
    • Causes terminal potential difference to be less than EMF
  • Internal resistances of cells in series
    Add up
  • Internal resistances of cells in parallel

    Decrease in effect