TY - JOUR
T1 - In situ formation of thermoset matrices for improved stability in organic photovoltaics
AU - Han, Jianhua
AU - Xu, Han
AU - Sharma, Anirudh
AU - Babics, Maxime
AU - Bertrandie, Jules
AU - Wang, Xunchang
AU - Huerta Hernandez, Luis
AU - Zhang, Yongcao
AU - Wen, Yuanfan
AU - Rosas Villalva, Diego
AU - Ramos, Nicolas
AU - Paleti, Sri Harish K.
AU - Martin, Jaime
AU - Xu, Fuzong
AU - Troughton, Joel
AU - Yang, Renqiang
AU - Gorenflot, Julien
AU - Laquai, Frédéric
AU - De Wolf, Stefaan
AU - Baran, Derya
N1 - Publisher Copyright:
© 2024 Elsevier Inc.
PY - 2024/10/16
Y1 - 2024/10/16
N2 - The performance of organic photovoltaics (OPVs) has rapidly increased. Yet, achieving long-term stability in the nano-morphology and thereby sustaining device performance remains challenging. Herein, we show that incorporating in-situ-forming cross-linked thermoset (CLT) matrices into the bulk heterojunction blends is a simple, general, and efficient strategy for high-performing and resilient OPVs. Our simulations and experimental data prove that these high-modulus CLT matrices featuring hydrogen-bonding interactions can freeze the nano-morphology, resulting in long-term thermal and photostable OPV devices. We demonstrate that this approach works efficiently with eight different blends and show that OPV devices can withstand 85°C for 1,000 h without losing performance. Blends with CLT matrices double the energy generated from OPV devices, showing an energy density output of 4,054 mW⋅h cm−2 over an 11-week operating period under outdoor conditions. This methodology opens avenues for both developing new thermoset networks for OPV and their use in other optoelectronic applications.
AB - The performance of organic photovoltaics (OPVs) has rapidly increased. Yet, achieving long-term stability in the nano-morphology and thereby sustaining device performance remains challenging. Herein, we show that incorporating in-situ-forming cross-linked thermoset (CLT) matrices into the bulk heterojunction blends is a simple, general, and efficient strategy for high-performing and resilient OPVs. Our simulations and experimental data prove that these high-modulus CLT matrices featuring hydrogen-bonding interactions can freeze the nano-morphology, resulting in long-term thermal and photostable OPV devices. We demonstrate that this approach works efficiently with eight different blends and show that OPV devices can withstand 85°C for 1,000 h without losing performance. Blends with CLT matrices double the energy generated from OPV devices, showing an energy density output of 4,054 mW⋅h cm−2 over an 11-week operating period under outdoor conditions. This methodology opens avenues for both developing new thermoset networks for OPV and their use in other optoelectronic applications.
KW - dynamic mechanical analysis
KW - glass transition temperature
KW - hydrogen-bonding interactions
KW - morphological stability
KW - organic solar cells
KW - outdoor stability
KW - thermal mechanical behavior
KW - thermal stability
UR - http://www.scopus.com/inward/record.url?scp=85200474029&partnerID=8YFLogxK
U2 - 10.1016/j.joule.2024.07.008
DO - 10.1016/j.joule.2024.07.008
M3 - Article
AN - SCOPUS:85200474029
SN - 2542-4351
VL - 8
SP - 2883
EP - 2902
JO - Joule
JF - Joule
IS - 10
ER -