Network-Stabilized Bulk Heterojunction Organic Photovoltaics

Mok, Jorge Wu; Hu, Zhiqi; Sun, Changxu; Barth, Isaiah; Muñoz, Rodrigo; Jackson, Joshua; Terlier, Tanguy; Yager, Kevin G.; Verduzco, Rafael

doi:10.1021/acs.chemmater.8b03791

Title: Network-Stabilized Bulk Heterojunction Organic Photovoltaics

Journal Article · Fri Oct 26 00:00:00 EDT 2018 · Chemistry of Materials

DOI:https://doi.org/10.1021/acs.chemmater.8b03791· OSTI ID:1489739

Mok, Jorge Wu ^[1]; Hu, Zhiqi ^[1]; Sun, Changxu ^[1]; Barth, Isaiah ^[1]; Muñoz, Rodrigo ^[2]; Jackson, Joshua ^[2]; Terlier, Tanguy ^[1];

^[3];

^[1]

Rice Univ., Houston, TX (United States)
Rice Univ., Houston, TX (United States); Houston Community College, Houston, TX (United States)
Brookhaven National Lab. (BNL), Upton, NY (United States)

Bulk heterojunction organic photovoltaic (OPV) devices are multilayer organic devices that can be fabricated using low-cost and scalable solution processing methods, but current devices exhibit poor mechanical stability and degrade under deformation due to cracking and delamination. Recent approaches to improve mechanical durability involve modifying the side-chain or main-chain structures of conjugated polymers in the active layer, but in general it is difficult to simultaneously optimize electronic properties, morphology, and mechanical stability. Here, we present a general approach to improve the mechanical stability of bulk heterojunction active layers through incorporation of an internal elastic network. Network-stabilized bulk heterojunction OPVs are prepared using reactive small molecular additives that are rapidly cross-linked through thiol–ene coupling after processing the active layer. Thiol–ene reactions catalyzed by a base or initiated through short exposure to UV light produce insoluble, elastic thiol–ene networks in the active layer. We show through a combination of crack onset strain measurements, morphological analysis, and OPV device testing that network-stabilized OPVs with up to 20% thiol–ene network exhibit improved deformability with no loss in PCE, and we implement network-stabilized bulk heterojunction OPVs to produce stretchable photovoltaic devices. Here, this work represents a simple approach for improving the mechanical durability of bulk heterojunction OPVs.

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