Experimental demonstration of ions induced electric field in perovskite solar cells

TL;DR

This paper experimentally demonstrates how ion migration in perovskite solar cells induces an electric field, affecting hysteresis, photovoltaic effects, and stability, with implications for device performance and negative capacitance phenomena.

Contribution

It provides direct experimental evidence of ions-induced electric fields in perovskite solar cells and explores their impact on hysteresis and device stability.

Findings

Ion migration induces a switchable electric field in perovskite solar cells.

External voltage influences the stability and hysteresis behavior.

Negative capacitance observed at low frequency linked to ion charge reversal.

Abstract

The anomalous hysteresis is reported in photo current density-voltage (J-V) curves of perovskite solar cells. The origins responsible for hysteresis are primarily attributed to ferroelectricity, trapping/de-trapping, and ions migration. Meanwhile, a switchable photovoltaic effect is disclosed in lateral structure perovskite solar cells, where a p-i-n structure is formed after poling the device with a reverse bias. Considering the normal sandwiched structure of perovskite solar cells, i.e. the intrinsic perovskite layer is situated in an electric field built by p-type (Spiro-OMeTAD) and n-type (TiO2) layers, the poling process also works in such devices. The migration of ions will induce a new electric field with opposite direction as inherent built-in electric field. As a consequence, less collection of photogenerated carriers is predicted due to the built-in electric field is partially screened. Here, the ions induced electric field is experimentally demonstrated by exploring the external quantum efficiency (EQE) spectra under various forward voltage biases. The anomalous hysteresis observed on J-V curves is explained based on the insight of ions migrations under bias voltage. The external applied voltage presents significant influence on the stability of solar cells. Meanwhile, a novel phenomenon of negative capacitance is initially detected at low frequency, which is ascribed to the position reversal of negatively and positively charged ions under forward bias.