Column $I$ gives certain situations in which a straight metallic wire of resistance $R$ is used and Column $II$ gives some resulting effects. Match the statements in Column $I$ with the statements in Column $II$.
Column $I$ Column $II$ $(A)$ $A$ charged capacitor is connected to the ends of the wire $(p)$ $A$ constant current flows through the wire $(B)$ The wire is moved perpendicular to its length with a constant velocity in a uniform magnetic field perpendicular to the plane of motion $(q)$ Thermal energy is generated in the wire $(C)$ The wire is placed in a constant electric field that has a direction along the length of the wire $(r)$ $A$ constant potential difference develops between the ends of the wire $(D)$ $A$ battery of constant emf is connected to the ends of the wire $(s)$ Charges of constant magnitude appear at the ends of the wire
| Column $I$ | Column $II$ |
| $(A)$ $A$ charged capacitor is connected to the ends of the wire | $(p)$ $A$ constant current flows through the wire |
| $(B)$ The wire is moved perpendicular to its length with a constant velocity in a uniform magnetic field perpendicular to the plane of motion | $(q)$ Thermal energy is generated in the wire |
| $(C)$ The wire is placed in a constant electric field that has a direction along the length of the wire | $(r)$ $A$ constant potential difference develops between the ends of the wire |
| $(D)$ $A$ battery of constant emf is connected to the ends of the wire | $(s)$ Charges of constant magnitude appear at the ends of the wire |
- A$A \rightarrow (q), B \rightarrow (r, s), C \rightarrow (r, s), D \rightarrow (p, q, r)$
- B$A \rightarrow (r), B \rightarrow (r, s), C \rightarrow (r, s), D \rightarrow (p, s, q)$
- C$A \rightarrow (r), B \rightarrow (s, q), C \rightarrow (r, s), D \rightarrow (p, s, r)$
- D$A \rightarrow (s), B \rightarrow (q, s), C \rightarrow (s, s), D \rightarrow (p, q, r)$
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