Yao Liang, Guijarro Néstor, Boudoire Florent, Liu Yongpeng, Rahmanudin Aiman, Wells Rebekah A, Sekar Arvindh, Cho Han-Hee, Yum Jun-Ho, Le Formal Florian, Sivula Kevin
Laboratory for Molecular Engineering of Optoelectronic Nanomaterials, Institute of Chemical Sciences and Engineering, École Polytechnique Fédérale de Lausanne (EPFL), Station 6, 1015 Lausanne, Switzerland.
J Am Chem Soc. 2020 Apr 29;142(17):7795-7802. doi: 10.1021/jacs.0c00126. Epub 2020 Apr 20.
As organic semiconductors attract increasing attention to application in the fields of bioelectronics and artificial photosynthesis, understanding the factors that determine their robust operation in direct contact with aqueous electrolytes becomes a critical task. Herein we uncover critical factors that influence the operational stability of donor:acceptor bulk heterojunction photocathodes for solar hydrogen production and significantly advance their performance under operational conditions. First, using the direct photoelectrochemical reduction of aqueous Eu and impedance spectroscopy, we determine that replacing the commonly used fullerene-based electron acceptor with a perylene diimide-based polymer drastically increases operational stability and identify that limiting the photogenerated electron accumulation at the organic/water interface to values of ca. 100 nC cm is required for stable operation (>12 h). These insights are extended to solar-driven hydrogen production using MoS, MoP, or RuO water reduction catalyst overlayers where it is found that the catalyst morphology strongly affects performance due to differences in charge extraction. Optimized performance of bulk heterojunction photocathodes coated with a MoS:MoP composite gave 1 Sun photocurrent density up to 8.7 mA cm at 0 V vs RHE (pH 1). However, increased stability was gained with RuO where initial photocurrent density (>8 mA cm) deceased only 15% or 33% during continuous operation for 8 or 20 h, respectively, thus demonstrating unprecedented robustness without a protection layer. This performance represents a new benchmark for organic semiconductor photocathodes for solar fuel production and advances the understanding of stability criteria for organic semiconductor/water-junction-based devices.
随着有机半导体在生物电子学和人工光合作用领域的应用受到越来越多的关注,了解决定其与水性电解质直接接触时稳定运行的因素成为一项关键任务。在此,我们揭示了影响供体:受体体相异质结光阴极用于太阳能制氢的运行稳定性的关键因素,并显著提高了它们在运行条件下的性能。首先,通过Eu水溶液的直接光电化学还原和阻抗谱,我们确定用苝二酰亚胺基聚合物取代常用的富勒烯基电子受体可大幅提高运行稳定性,并确定将光生电子在有机/水界面处的积累限制在约100 nC cm²的值是稳定运行(>12小时)所必需的。这些见解扩展到使用MoS₂、MoP或RuO₂析氢催化剂覆盖层的太阳能驱动制氢,发现由于电荷提取的差异,催化剂形态强烈影响性能。涂覆有MoS₂:MoP复合材料的体相异质结光阴极的优化性能在相对于可逆氢电极(RHE)为0 V(pH 1)时,1个太阳光下的光电流密度高达8.7 mA cm⁻²。然而,使用RuO₂时稳定性提高,初始光电流密度(>8 mA cm⁻²)在连续运行8小时或20小时期间分别仅下降了15%或33%,从而证明了在没有保护层的情况下具有前所未有的稳健性。这种性能代表了用于太阳能燃料生产的有机半导体光阴极的新基准,并推进了对基于有机半导体/水结器件的稳定性标准的理解。
