Platform molecular materials and surfaces for solar fuels generation

用于太阳能燃料发电的平台分子材料和表面

• 批准号: RGPIN-2018-04391
• 负责人: Majewski, Marek
• 金额: $ 2.04万
• 依托单位: Concordia University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=712963
• 关键词: Platform; molecular; materials; surfaces; solar

The proposed research program seeks to understand how systems can use sunlight to generate charges to drive catalysts for solar fuels generation. This goal is realized through building an understanding of and characterizing the basic phenomena of solar energy conversion dynamics, by engineering and synthesizing nano- and mesoscale architectures with targeted functionality, and by combining solar energy conversion phenomena across time and space. More specifically, this proposal seeks to answer the following central questions: how does the structure of molecular materials determine the efficiency of light capture and charge transport, and how can material properties be modified to take advantage of hierarchical assembly for systems scalable from the nano- to the mesoscale? Solar fuels catalysis relies on single electron transfer events between a chromophore/catalyst and/or a substrate. To drive catalysis in bimolecular reactions that occur after photon absorption, careful redox leveling must be implemented across all components. In the first major focus of this work a hierarchical approach to designing, preparing, and characterizing solar fuels catalysts will be undertaken. While mechanistic investigations are often easier to carry out in homogeneous systems, heterogeneous catalysts benefit from increased stability and recyclability. A combination of both approaches involves the adsorption of molecular chromophores and known catalysts onto heterogeneous semiconductor surfaces. Few photoelectrochemical (PEC) cells that combine molecular catalysts, dyes and semiconductor surfaces exist, due to the array of variables that must be optimized to make a functioning dye sensitized photoelectrochemical device (DS-PEC). In the second major focus of this proposal, tandem DS-PEC devices will be developed utilizing a bottom-up approach. Semiconductors will be grown on surfaces and subsequently functionalized by adsorbing inorganic supramolecular chromophore-catalyst assemblies. Electrochemical measurements in the presence of light irradiation will confirm reduction or oxidation of catalysts present in proximity to the chromophores, while prolonged irradiation in the presence of catalytic amounts of either water or acid in a sealed electrochemical cell will yield measurable amounts of desired gasses (O2 and H2). The long-term vision of this work is to develop fundamental understanding coupled with materials and methods to engineer dramatically more efficient technologies for solar fuels production (e.g. conversion of CO2 to value added products, or the reduction of protons to hydrogen). Ultimately, this strategy affords the engineering of energy conversion systems operating with exceptional performance while mentoring a technically exceptional workforce capable of solving energy-related problems far into the future.

拟议的研究计划旨在了解系统如何利用阳光产生电荷来驱动太阳能燃料发电的催化剂。这一目标是通过建立对太阳能转换动力学基本现象的理解和表征，通过设计和合成具有目标功能的纳米和中尺度架构，以及通过跨时间和空间组合太阳能转换现象来实现的。更具体地说，该提案旨在回答以下中心问题：分子材料的结构如何决定光捕获和电荷传输的效率，以及如何修改材料特性以利用从纳米尺度到中尺度可扩展的系统的分级组装？ 太阳能燃料催化依赖于发色团/催化剂和/或基底之间的单电子转移事件。为了驱动光子吸收后发生的双分子反应中的催化作用，必须在所有组件上实施仔细的氧化还原平衡。在这项工作的第一个主要重点是分层的方法来设计，制备和表征太阳能燃料催化剂将进行。虽然机理研究通常更容易在均相体系中进行，但非均相催化剂受益于增加的稳定性和可回收性。两种方法的组合涉及分子发色团和已知催化剂吸附到异质半导体表面上。由于必须优化一系列变量以制造起作用的染料敏化光电化学装置（DS-PEC），因此存在很少的将分子催化剂、染料和半导体表面组合的联合收割机光电化学（PEC）电池。 在本提案的第二个主要重点中，将利用自下而上的方法开发串联DS-PEC器件。半导体将在表面上生长，随后通过吸附无机超分子发色团-催化剂组装体来官能化。在光照射存在下的电化学测量将确认存在于发色团附近的催化剂的还原或氧化，而在密封电化学电池中在催化量的水或酸存在下的长时间照射将产生可测量量的所需气体（O2和H2）。 这项工作的长期愿景是发展与材料和方法相结合的基本理解，以设计更有效的太阳能燃料生产技术（例如将二氧化碳转化为增值产品，或将质子还原为氢）。最终，这一战略提供了具有卓越性能的能源转换系统的工程设计，同时指导了能够解决未来能源相关问题的技术卓越的员工队伍。