Infrared Solution‐Processed Quantum Dot Solar Cells Reaching External Quantum Efficiency of 80% at 1.35 µm and Jsc in Excess of 34 mA cm−2

Azmi; Brown; Brown; Burkhard; Bush; Cao; Carey; Centurioni; Choi; Choi; Choi; Chuang; Chuang; Dirin; Eperon; Gao; Guchhait; Hou; Ip; Ip; Ip; Jasieniak; Kiani; Kirchartz; Lai; Lan; Lan; Lee; Liu; Liu; Miller; Pettersson; Pradhan; Shockley; Speirs; Stavrinadis; Stavrinadis; Tan; Todorov; Vos; Wang; Zherebetskyy

research

Infrared Solution‐Processed Quantum Dot Solar Cells Reaching External Quantum Efficiency of 80% at 1.35 µm and Jsc in Excess of 34 mA cm−2

Authors: Azmi
Brown
Brown
Burkhard
Bush
Cao
Carey
Centurioni
Choi
Choi
Choi
Chuang
Chuang
Dirin
Eperon
Gao
Guchhait
Hou
Ip
Ip
Ip
Jasieniak
Kiani
Kirchartz
Lai
Lan
Lan
Lee
Liu
Liu
Miller
Pettersson
Pradhan
Shockley
Speirs
Stavrinadis
Stavrinadis
Tan
Todorov
Vos
Wang
Zherebetskyy
Publication date: 1 January 2018
Publisher: 'Wiley'
Doi

Abstract

Developing low‐cost photovoltaic absorbers that can harvest the short‐wave infrared (SWIR) part of the solar spectrum, which remains unharnessed by current Si‐based and perovskite photovoltaic technologies, is a prerequisite for making high‐efficiency, low‐cost tandem solar cells. Here, infrared PbS colloidal quantum dot (CQD) solar cells employing a hybrid inorganic–organic ligand exchange process that results in an external quantum efficiency of 80% at 1.35 µm are reported, leading to a short‐circuit current density of 34 mA cm−2 and a power conversion efficiency (PCE) up to 7.9%, which is a current record for SWIR CQD solar cells. When this cell is placed at the back of an MAPbI3 perovskite film, it delivers an extra 3.3% PCE by harnessing light beyond 750 nm.Peer ReviewedPostprint (author's final draft