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Enhancing Photovoltaic and Photosensing Performances in Bismuth Ferrite via Polar Order Engineering

Chi‐Shun Tu, Yi-Shin Jou, Pin-Yi Chen, Cheng‐Sao Chen, Yu-Chen Hsu, Kuei‐Chih Feng, R. R. Chien, V. Hugo Schmidt, Shu‐Chih Haw

2020ACS Applied Electronic Materials28 citationsDOI

Abstract

Recent emerging developments have demonstrated that bismuth ferrite is one of the promising lead-free perovskite materials used in solar energy harvesting devices and photodetectors. This work reports high short-circuit photocurrent densities of ∼1.2 × 103 and ∼0.55 × 103 μA/cm2 in a p-type gadolinium-doped BiFeO3 ceramic with n-type indium tin oxide under 405 nm irradiation and sunlight at 102 mW/cm2 intensity, respectively. Polarization-enhanced photoresponsivity of ∼5.4 × 10–2 A/W and specific detectivity of ∼1.5 × 1011 Jones were achieved with response times of ∼1 and ∼10 ms, respectively, at the rising and decaying edges. Enhanced photovoltaic conversion via a prior electric-field poling can be attributed to the p–n junction and the field-modulated Schottky barrier in conjunction with domain nucleation, ordered polar nanoregions, and increased O 2p–Fe 3d orbital hybridization. The network of domain walls and grain boundaries serves as conduction pathways for the photogenerated charge carriers. The improved photocurrent in gadolinium-doped BiFeO3 opens up an opportunity for using bismuth ferrite materials in self-powered photodetectors.

Topics & Concepts

Materials scienceBismuth ferritePhotocurrentOptoelectronicsPolingSchottky barrierSchottky diodePhotodetectorPerovskite (structure)BismuthFerroelectricityMultiferroicsChemistryDiodeMetallurgyCrystallographyDielectricMultiferroics and related materialsDielectric properties of ceramicsPerovskite Materials and Applications
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