5.4 Electromotive force and internal resistance

    Cards (53)

    • Electromotive force (EMF) is the potential difference that a source of electrical energy can provide when there is no current flowing
    • Match the property with its definition:
      EMF (ε) ↔️ The maximum potential difference the source can provide
      Terminal Potential Difference (V) ↔️ The actual potential difference across the terminals when current is flowing
      Internal Resistance (r) ↔️ The resistance within the source that causes a voltage drop
    • EMF is measured with no current flowing
    • EMF represents the maximum voltage a source can provide, while PD is the actual voltage across the terminals when current flows.
      True
    • Internal resistance reduces the terminal potential difference below the EMF
    • Under what condition is potential difference measured?
      Current flowing
    • Internal resistance within a battery causes a voltage drop
    • The internal resistance of a battery reduces the terminal potential difference below the EMF
    • Higher temperatures generally decrease the internal resistance of a battery.

      True
    • The terminal potential difference is the actual voltage across a battery's terminals when current is flowing.
    • The EMF is measured when no current is flowing in the circuit.
      True
    • Match the term in the EMF equation with its definition:
      V ↔️ Terminal potential difference
      ε ↔️ Electromotive force
      I ↔️ Current
      r ↔️ Internal resistance
    • What is the formula that relates EMF, terminal potential difference, current, and internal resistance?
      V=V =εIr \varepsilon - Ir
    • The terminal potential difference is the EMF minus the voltage drop across the internal resistance.

      True
    • Electromotive force is the potential difference when no current is flowing.
    • Match the property with its description:
      EMF ↔️ Maximum potential difference when no current flows
      PD ↔️ Voltage across terminals when current flows
      Internal Resistance ↔️ Resistance within the source causing voltage drop
    • Order the factors affecting internal resistance:
      1️⃣ Battery Age
      2️⃣ Temperature
      3️⃣ Battery Composition
      4️⃣ Discharge Rate
    • What is the power output of a 12V battery with 0.5Ω internal resistance supplying 2A of current?
      22W
    • If a battery has an EMF of 12V, internal resistance of 0.5Ω, and a current of 2A, the terminal potential difference is 11V.

      True
    • The terminal potential difference is equal to the EMF when no current is flowing.
      False
    • Match the property with its description:
      EMF ↔️ Maximum voltage when no current flows
      Terminal Potential Difference ↔️ Actual voltage during current flow
    • The EMF equation relates the terminal potential difference, EMF, current, and internal
    • What are the units of terminal potential difference?
      Volts
    • The EMF equation can only be used when current is flowing in the circuit.

      True
    • What is the terminal potential difference if the EMF is 12V, internal resistance is 0.5Ω, and current is 2A?
      11V
    • The terminal potential difference is the same as the EMF when there is no internal resistance.

      True
    • What does EMF represent in a source of electrical energy?
      Maximum possible voltage
    • The relationship between EMF, terminal potential difference, and internal resistance is described by V=V =εIr \varepsilon - Ir.

      True
    • What is the formula relating EMF, terminal potential difference, internal resistance, and current?
      V=V =εIr \varepsilon - Ir
    • When is EMF measured in a circuit?
      No current flowing
    • Ordering the factors affecting internal resistance in batteries:
      1️⃣ Battery Age
      2️⃣ Battery Composition
      3️⃣ Discharge Rate
      4️⃣ Temperature
    • What happens to internal resistance as a battery ages?
      Increases
    • Higher temperatures generally decrease internal resistance.
    • Battery age increases internal resistance due to chemical degradation
      True
    • Order the steps of how temperature affects internal resistance:
      1️⃣ Higher temperature increases chemical reaction efficiency
      2️⃣ Chemical degradation decreases internal resistance
      3️⃣ Voltage drop is reduced
    • The internal resistance of a battery causes a voltage drop that reduces the terminal potential difference.
    • Match the property with its correct description for EMF and terminal potential difference:
      EMF (ε) ↔️ Maximum potential difference the source can provide
      Terminal Potential Difference (V) ↔️ Actual voltage when current flows
    • The EMF equation relates the terminal potential difference, the electromotive force, the current, and the internal resistance.
    • The EMF equation shows that the terminal potential difference is the EMF minus the voltage drop across the internal resistance.

      True
    • The EMF equation relates terminal potential difference to current, electromotive force, and internal resistance