S-Q Charts

Figures last updated on 17 Feb. 2017 by Tom Veeken.
Please contact us with new record-efficiency solar cell data at veeken@amolf.nl.

The figures shown below provide an up-to-date comparison between world-record single junction solar cells and the fundamental Shockley-Queisser detailed-balance model. These plots may be used with attribution to both this website (lmpv.amolf.nl/SQ) and the following article:

Albert Polman, Mark W. Knight, Erik C. Garnett, Bruno Ehrler, Wim C. Sinke. Photovoltaic materials: Present efficiencies and future challenges. Science 352, aad4424 (2016). DOI: 10.1126/science.aad4424.

Efficiencies relative to Shockley-Queisser

Fraction of the Shockley-Queisser detailed-balance limit (black line) achieved by record-efficiency cells, gray lines showing 75% and 50% of the limit.

Optical and electrical fractions

The current ratio j = Jsc/ JSQ plotted versus the product of the voltage and fill factor fractions (v x f = FF Voc / FFSQ VSQ) for record-efficiency cells. The lines around some data points correspond to a range of band gaps taken in the S-Q calculations according to uncertainty in the band gap of the record cell.

Current, voltage, and FF

Single-junction solar cell parameters are shown as a function of band gap energy according to the Shockley-Queisser limit (solid lines) and experimental values for record-efficiency cells.

Panel 1: short-circuit current Jsc.

Panel 2: Open-circuit voltage Voc. The voltage corresponding to the band gap is shown for reference, with the voltage gap Vg-VSQ indicated by the gray shaded region.

Panel 3: Fill factor FF = (JmpVmp)/(VocJsc). All data are for standard AM1.5 illumination at 1000 W/m2.


References for record-efficiency cells in the updated figures

Crystalline silicon
Multicrystalline silicon
Amorphous silicon
Nanocrystalline silicon
GaAs 
InP
GaInP
CdTe
CIGS
CZTS
Dye/TiO2
Organic
Quantum-dots
Perovskite