Solar Cell Efficiency Formula

In order to ensure that different solar cells are compared consistently within the field of solar cell research, we use a standard formula for determining their efficiency. This standardised efficiency is known as the power conversion efficiency (PCE) and it is defined using the following equation:

Power Conversion Efficiency (PCE) equation

PCE represents the conversion ratio of incident power from light energy to usable electrical power. It is determined by three properties of the solar cell, and one property of the incident spectrum:

Short circuit current (J_SC)
Open circuit voltage (V_OC)
Fill factor (FF)
Incident power irradiance (P_in)

J_SC, V_OC and FF can all be measured directly from an I-V curve measurement. When measuring solar cells, we often refer to current density, J, rather than just the current, I. This is because the amount of current extracted from a solar cell will depend on the size of the active area. By using current density J instead of I, we can compare the device performance of solar cells with different active areas. It is therefore important that you measure the active area of your device (the area that will be illuminated) very precisely, especially when measuring small-area PV devices.

P_in will depend on the solar simulator light source that you use; however, all solar simulators should provide power irradiance of 1 Sun, 100 mW/cm² or 1000 W/m² at the device surface. It is therefore important that your solar simulator is correctly calibrated to replicate the solar spectrum accurately.

You can find the J_SC, V_OC and FF (and subsequently PCE) of your device from a current voltage measurement. This is when you measure the current density running through your device at incremental voltages. This measurement will give you a I-V curve (or more specifically a J-V curve), which will follow the equivalent circuit model of a solar cell.

Characterization of solar cells — Example current-voltage curve of a PV device plotted using current density (J). The short-circuit current density (*J_SC*), open-circuit voltage (*V_OC*), current and voltage at maximum power (*J_MP* and *V_MP* respectively), maximum power point (*P_Max*), and fill factor (FF) are highlighted.

J_SC is the current at which there is zero potential difference across the solar cell. Likewise, V_OC is the voltage at which there is zero current flowing through the device. Therefore, you can easily find both J_SC and V_OC on an IV curve at the y-intercept and the x-intercept respectively. Fill factor is a little more difficult to define - it is a measure of the "squareness" curve. There is a point on the curve where the J and V values are maximised to form the maximum power point (MP). These are called J_MP and V_MP respectively, and they create a shaded rectangular area of theoretical maximum power available through J_MP x V_MP. You can then calculate fill factor using the following equation:

You can find J_MP and V_MP by working out the point at which J x V is largest. This should be done computationally to ensure that your measurements are consistent.

Learn More

The AM1.5 Spectrum

Solar irradiance varies depending on where you are in the world. This is because of a combination of local atmospheric conditions and geometric considerations.

Contributing Authors

Written by

Dr. Mary O'Kane

Application Scientist