TY - GEN
T1 - A new concept to break the space charge limit of organic semiconductors for photovoltaic applications
AU - Choy, Wallace C.H.
AU - Sha, W. E.I.
AU - Li, X.
AU - Zhu, L.
N1 - Publisher Copyright:
© 2017 IEEE.
PY - 2017
Y1 - 2017
N2 - As a fundamental electrostatic limit, the space charge limit (SCL) for photocurrent is a universal feature and of paramount importance in organic semiconductors with unbalanced electron/hole mobility and high exciton generation. Here, we propose a new concept of plasmonic-electrical effect to manipulate the electrical properties (photocarrier generation, recombination, transport, and collection) of semiconductor devices with the help of plasmonically induced light redistribution. As a proof-of-concept, organic solar cells (OSCs) incorporating metallic planar and grating anodes are systematically investigated for normal and inverted device structures. Interestingly, although strong plasmonic resonances induce abnormally dense photocarriers around a grating anode, the grating-inverted OSC is exempt from space charge accumulation (limit) and degradation of electrical properties in contrast to the planar-inverted and planar-normal ones. It is because abnormally redistributed holes by the plasmonic-electrical effect, despite of the typically low mobility of holes, shorten hopping path of low mobility holes to reach the grating anode. Consequently, the work contributes to the evolution of device architecture to break the SCL with detailed multiphysics explanations. Moreover, the proposed plasmon-electrical concept will open up a novel way to manipulate both optical and electrical properties of organic semiconductor devices for photovoltaic applications.
AB - As a fundamental electrostatic limit, the space charge limit (SCL) for photocurrent is a universal feature and of paramount importance in organic semiconductors with unbalanced electron/hole mobility and high exciton generation. Here, we propose a new concept of plasmonic-electrical effect to manipulate the electrical properties (photocarrier generation, recombination, transport, and collection) of semiconductor devices with the help of plasmonically induced light redistribution. As a proof-of-concept, organic solar cells (OSCs) incorporating metallic planar and grating anodes are systematically investigated for normal and inverted device structures. Interestingly, although strong plasmonic resonances induce abnormally dense photocarriers around a grating anode, the grating-inverted OSC is exempt from space charge accumulation (limit) and degradation of electrical properties in contrast to the planar-inverted and planar-normal ones. It is because abnormally redistributed holes by the plasmonic-electrical effect, despite of the typically low mobility of holes, shorten hopping path of low mobility holes to reach the grating anode. Consequently, the work contributes to the evolution of device architecture to break the SCL with detailed multiphysics explanations. Moreover, the proposed plasmon-electrical concept will open up a novel way to manipulate both optical and electrical properties of organic semiconductor devices for photovoltaic applications.
KW - Light trapping
KW - Organic semiconductors
KW - Photovoltaic cells
KW - Plasmons
UR - http://www.scopus.com/inward/record.url?scp=85048491604&partnerID=8YFLogxK
U2 - 10.1109/PVSC.2017.8366196
DO - 10.1109/PVSC.2017.8366196
M3 - 会议稿件
AN - SCOPUS:85048491604
T3 - 2017 IEEE 44th Photovoltaic Specialist Conference, PVSC 2017
SP - 2355
EP - 2357
BT - 2017 IEEE 44th Photovoltaic Specialist Conference, PVSC 2017
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 44th IEEE Photovoltaic Specialist Conference, PVSC 2017
Y2 - 25 June 2017 through 30 June 2017
ER -
