Movement of cracked silicon solar cells during module temperature changes

Cracks in crystalline silicon solar cells can lead to substantial power loss. While the cells’ metal contacts can initially bridge these cracks and maintain electrical connections, the bridges are damaged by mechanical loads, including those due to temperature changes. We investigated the metallization bridges that form over cracks in encapsulated silicon solar cells. Microscopic characterization showed that the crack in the silicon can immediately propagate through the metal grid, but the grid can maintain electrical contact once the load is removed. We also quantified the movement of the cell fragments separated by a crack as a function of temperature. Cell fragments are free to move diagonally and to rotate, so the change in gap across the crack during a temperature change varies along the length of the crack. In one sample, we showed that a 10 ◦C temperature change, causing a 2 µm increase in the separation of cell fragments, was sufficient to cause a reversible electrical disconnection of metallization bridging a crack.