Ti3C2Tx (MXene)-Silicon Heterojunction for Efficient Photovoltaic Cells

Yu, LePing; Bati, Abdulaziz SR; Grace, Tom SL; Batmunkh, Munkhbayar; Shapter, Joseph G

doi:10.1002/aenm.201901063

Author(s)

Yu, LePing

Bati, Abdulaziz SR

Grace, Tom SL

Batmunkh, Munkhbayar

Shapter, Joseph G

Griffith University Author(s)

Batmunkh, Munkhbayar

Year published

2019

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Abstract

A novel type of solar cell has been developed based on charge separation at the heterojunction formed by a transparent conducting MXene electrode and an n-type silicon (n-Si) wafer. A thin layer of the native silicon dioxide plays an important role in suppressing the recombination of charge carriers. A two-step chemical treatment can increase the device efficiency by about 40%. Promisingly, an average power conversion efficiency of over 10% under simulated full sunlight is achieved for this novel class of solar cell with the application of an antireflection layer. The efficiencies of these novel solar cells based on a MXene-Si ...
View more >A novel type of solar cell has been developed based on charge separation at the heterojunction formed by a transparent conducting MXene electrode and an n-type silicon (n-Si) wafer. A thin layer of the native silicon dioxide plays an important role in suppressing the recombination of charge carriers. A two-step chemical treatment can increase the device efficiency by about 40%. Promisingly, an average power conversion efficiency of over 10% under simulated full sunlight is achieved for this novel class of solar cell with the application of an antireflection layer. The efficiencies of these novel solar cells based on a MXene-Si heterojunction achieved in this work point to great promise in emerging photovoltaic technology. In addition to their high efficiency, the excellent reproducibility of such devices establishes a solid base for possible future commercialization.
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