Piezoelectric-enhanced p-n junctions in photoelectrochemical systems

Credit: Green Energy & Environment

THE FORMED BUILT-IN ELECTRIC FIELD AND POLARIZED-INDUCED ELECTRIC FIELD AT THE INTERFACE OF HETEROJUNCTION TO PROMOTE CARRIER SEPARATION.

Newswise — Photoelectrochemical (PEC) water splitting is a potentially feasible strategy for converting solar energy to green hydrogen. However, current PEC systems suffer from relatively low charge separation efficiency and sluggish water oxidation reaction, which prevent them from meeting the needs of practical applications. The main bottleneck like in achieving effective charge spatial separation, which is crucial for achieving efficient solar-to-hydrogen conversion.

Heterojunction engineering is one of the most promising methods for spatial charge separation, yet the carrier separation efficiency of heterojunction remains limited due to energy band matching or interfacial and structural compatibility between different semiconductors. Meanwhile, the construction of p-n homojunction by finely controlling dopant or defect in semiconductors has been proven to be feasible, but the phenomenon that neutralizes the interfacial electric field through rapid accumulation of carriers during transfer process is largely negligible.

To that end, a team of researchers from the School of Chemical Engineering and Technology at Tianjin University, designed a unique n-TiO₂/BaTiO₃/p-TiO₂ heterojunction which couples with piezoelectric effect and p-n junctions to overcome the charge separation and transfer limitation of p-n junction.

“In our designed heterojunction, the ferroelectric BaTiO₃ layer is between n-TiO₂ with oxygen vacancies and p-TiO₂ with titanium vacancies,” shares Minhua Ai, lead author of the study published in the KeAi journal Green Energy & Environment. “Consequently, the TBT3 achieves a prominent photocurrent density which is 2.4- and 1.5-times higher than TiO₂ and TiO₂–BaTiO₃ heterojunction, respectively.”

Notably, driven by mechanical deformation, a stable polarized electric field formed in ferroelectric BaTiO3 can further regulate built-in electric fields based on comprehensive characterizations of charge carrier behaviors in such a multi-heterojunction. And n-TiO₂/BaTiO₃/p-TiO₂ heterojunction achieve piezoelectric-enhanced PEC performance (2.84 times higher than TiO₂ at 1.23 V vs. RHE).

“Based on the coupling with piezoelectric effect and p-n junctions, our work provides a piezoelectric polarization strategy for modulating the built-in electric field of heterojunction for charge separation enhancement,” adds senior and corresponding author Lun Pan.