Abstract
Recent numerical modeling and experimental work have shown that appropriate conduction band alignment at the emitter/absorber interface is critically important for high efficiency CdTe solar cells. To date, however, the properties of the transparent conducting oxide (TCO)/emitter interface have not been thoroughly investigated. Here, we use numerical modeling to determine the role of the conduction band alignment at the TCO/emitter interface. Our findings are increasingly important to device performance as efforts are made to widen the bandgap of the absorber. We also investigate the relative importance of the barrier caused by poor front contact versus the barrier at the back contact. It is well known that a barrier at the back contact can reduce the open circuit voltage of the device and produce rollover in the current density-voltage but is not well appreciated that a barrier at the front of the device can play a completely analogous role. We also show that for optimum device performance at any absorber bandgap, the conduction band of the TCO must be no more than 0.3 eV below the conduction band of the emitter.
Highlights
Researchers at Colorado State University fabricated high efficiency CdTe devices by replacing the CdS emitter with Mg-doped ZnO (Mg1-xZnxO, or MZO).[1]
Because the MZO used for these devices had a bandgap (EG) of ∼3.7 eV (x = 0.23), the short wavelength response of the quantum efficiency (QE) showed no significant losses at energies below the EG of the transparent conducting oxide (TCO), and the QE data closely resembled the data for record CdTe cells.[2]
We focus on the role of the TCO/emitter band offset and explore the performance of devices fabricated with wide EG absorbers when the emitter/absorber spike is kept constant at an optimum value
Summary
Researchers at Colorado State University fabricated high efficiency CdTe devices by replacing the CdS emitter with Mg-doped ZnO (Mg1-xZnxO, or MZO).[1]. Role of band alignment at the transparent front contact/emitter interface in the performance of wide bandgap thin film solar cells
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