Band Offset Engineering in ZnSnN2-Based Heterojunction for Low-Cost Solar Cells

Kashif Javaid; Weihua Wu; Jun Wang; Junfeng Fang; Hongliang Zhang; Junhua Gao; Fei Zhuge; Lingyan Liang; Hongtao Cao

doi:10.1021/acsphotonics.8b00427

Band Offset Engineering in ZnSnN₂-Based Heterojunction for Low-Cost Solar Cells

Kashif Javaid
, Weihua Wu
, Jun Wang
, Junfeng Fang
, Hongliang Zhang
, Junhua Gao
, Fei Zhuge
, Lingyan Liang^*
, Hongtao Cao

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

60 Scopus citations

Abstract

A new ternary-alloy, zinc-tin nitride (ZnSnN₂), is considered as one of the most promising absorber materials for photovoltaic applications due to its ideal band gap, rich ternary-chemistry, robust optical absorption, and low cost. In the present work, we demonstrate the ZnSnN₂-based P-N and P-i-N heterojunctions to study the band offset engineering for the development of high-efficiency inorganic solar cell. The P-i-N heterojunction is composed of p-SnO, i-Al₂O₃, and n-ZnSnN₂ constituents. The inclusion of the i-Al₂O₃ buffer layer has remarkably improved the solar cell efficiency by regulating the conduction band offset and interface energy gap. It is believed that our present work will offer a promising approach to manufacture ZnSnN₂-based heterojunctions with better band alignment for novel photovoltaic applications.

Original language	English
Pages (from-to)	2094-2099
Number of pages	6
Journal	ACS Photonics
Volume	5
Issue number	6
DOIs	https://doi.org/10.1021/acsphotonics.8b00427
State	Published - 20 Jun 2018
Externally published	Yes

Keywords

AlO buffer layer
ZnSnN thin films
band alignment engineering
conduction band offset
heterojunction solar cell
interface energy gap

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This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1021/acsphotonics.8b00427

Cite this

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title = "Band Offset Engineering in ZnSnN2-Based Heterojunction for Low-Cost Solar Cells",

abstract = "A new ternary-alloy, zinc-tin nitride (ZnSnN2), is considered as one of the most promising absorber materials for photovoltaic applications due to its ideal band gap, rich ternary-chemistry, robust optical absorption, and low cost. In the present work, we demonstrate the ZnSnN2-based P-N and P-i-N heterojunctions to study the band offset engineering for the development of high-efficiency inorganic solar cell. The P-i-N heterojunction is composed of p-SnO, i-Al2O3, and n-ZnSnN2 constituents. The inclusion of the i-Al2O3 buffer layer has remarkably improved the solar cell efficiency by regulating the conduction band offset and interface energy gap. It is believed that our present work will offer a promising approach to manufacture ZnSnN2-based heterojunctions with better band alignment for novel photovoltaic applications.",

keywords = "AlO buffer layer, ZnSnN thin films, band alignment engineering, conduction band offset, heterojunction solar cell, interface energy gap",

author = "Kashif Javaid and Weihua Wu and Jun Wang and Junfeng Fang and Hongliang Zhang and Junhua Gao and Fei Zhuge and Lingyan Liang and Hongtao Cao",

note = "Publisher Copyright: {\textcopyright} 2018 American Chemical Society.",

year = "2018",

month = jun,

day = "20",

doi = "10.1021/acsphotonics.8b00427",

language = "英语",

volume = "5",

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T1 - Band Offset Engineering in ZnSnN2-Based Heterojunction for Low-Cost Solar Cells

AU - Javaid, Kashif

AU - Wu, Weihua

AU - Wang, Jun

AU - Fang, Junfeng

AU - Zhang, Hongliang

AU - Gao, Junhua

AU - Zhuge, Fei

AU - Liang, Lingyan

AU - Cao, Hongtao

PY - 2018/6/20

Y1 - 2018/6/20

N2 - A new ternary-alloy, zinc-tin nitride (ZnSnN2), is considered as one of the most promising absorber materials for photovoltaic applications due to its ideal band gap, rich ternary-chemistry, robust optical absorption, and low cost. In the present work, we demonstrate the ZnSnN2-based P-N and P-i-N heterojunctions to study the band offset engineering for the development of high-efficiency inorganic solar cell. The P-i-N heterojunction is composed of p-SnO, i-Al2O3, and n-ZnSnN2 constituents. The inclusion of the i-Al2O3 buffer layer has remarkably improved the solar cell efficiency by regulating the conduction band offset and interface energy gap. It is believed that our present work will offer a promising approach to manufacture ZnSnN2-based heterojunctions with better band alignment for novel photovoltaic applications.

AB - A new ternary-alloy, zinc-tin nitride (ZnSnN2), is considered as one of the most promising absorber materials for photovoltaic applications due to its ideal band gap, rich ternary-chemistry, robust optical absorption, and low cost. In the present work, we demonstrate the ZnSnN2-based P-N and P-i-N heterojunctions to study the band offset engineering for the development of high-efficiency inorganic solar cell. The P-i-N heterojunction is composed of p-SnO, i-Al2O3, and n-ZnSnN2 constituents. The inclusion of the i-Al2O3 buffer layer has remarkably improved the solar cell efficiency by regulating the conduction band offset and interface energy gap. It is believed that our present work will offer a promising approach to manufacture ZnSnN2-based heterojunctions with better band alignment for novel photovoltaic applications.

KW - AlO buffer layer

KW - ZnSnN thin films

KW - band alignment engineering

KW - conduction band offset

KW - heterojunction solar cell

KW - interface energy gap

UR - https://www.scopus.com/pages/publications/85047061973

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DO - 10.1021/acsphotonics.8b00427

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SN - 2330-4022

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