Six parallel-plate capacitors of identical plate separation have different plate areas A, different capacitances C, and different dielectrics filling the space between the plates. Below is a generic diagram of what each one of these capacitors might look like. (Figure 1) Part A Rank the following capacitors on the basis of the dielectric constant of the material between the plates. Rank from largest to smallest. To rank items as equivalent, overlap them. • View Available Hint(s) Reset Help A = 8 cm² C = 2 nF A = 2 cm? C = 4 nF A = 4 cm² C = 2 nF A =1 cm² C = 1 nF A = 4 cm? C = 1 nF A = 2 cm² C = 8 nF largest smallest O The correct ranking cannot be determined. Figure 1 of 1 Submit All of the capacitors from Part A are now attached to batteries with the same potential difference. + + |+ + + Part B Rank the capacitors on the basis of the charge stored on the positive plate. Rank from largest to smallest. To rank items as equivalent, overlap them.

Six parallel-plate capacitors of identical plate separation have different plate areas A, different capacitances C, and different dielectrics filling the space between the plates. Below is a generic diagram of what each one of these capacitors might look like. (Figure 1) Part A Rank the following capacitors on the basis of the dielectric constant of the material between the plates. Rank from largest to smallest. To rank items as equivalent, overlap them. • View Available Hint(s) Reset Help A = 8 cm² C = 2 nF A = 2 cm? C = 4 nF A = 4 cm² C = 2 nF A =1 cm² C = 1 nF A = 4 cm? C = 1 nF A = 2 cm² C = 8 nF largest smallest O The correct ranking cannot be determined. Figure 1 of 1 Submit All of the capacitors from Part A are now attached to batteries with the same potential difference. + + |+ + + Part B Rank the capacitors on the basis of the charge stored on the positive plate. Rank from largest to smallest. To rank items as equivalent, overlap them.