Organic Materials-based Electrochemical Flow Cells for Energy Applications

Abstract: To meet the 2015 Paris Agreement requirement of limiting global warming to 1.5 °C, the transition from fossil fuels to renewables (solar and wind) necessitates a rapid change of the energy landscape. The decline of the price for electricity from solar panels and wind turbines is so fast over the last decade that green electricity competes economically with electricity generated from coal, oil, and gas. Considering the output from renewable energy sources is electric current, the conversion and storage of green electricity is the key to the paradigm shift. Both conversion and storage imply transformation of electrical energy into chemical energy of molecules. The former means production of multipurpose energetic molecules. Here such a molecule is hydrogen peroxide, a green oxidant, and our aim is to advance its electrochemical production. The latter is concerned with making the chemical energy readily transformable back into electricity in batteries. In electrochemistry, H-cells are usually used in screening materials and mechanistic understanding of relevant processes. However, the results of H-cell studies sometimes do not directly translate to upscaled systems, such as flow cells. Electrochemical flow cells are attracting attention due to the ability to decouple capacity and power, the long operation time, and the decreased diffusion layer thickness and ohmic resistance. Most flow cells today use inorganic materials, and they are expensive and based on unsustainable mining processes in some geographically concentrated regions. Organic materials, on the contrary, are cheap and readily designed via molecular engineering and electro-organic synthesis. In this thesis, organic materials-based flow cells will be constructed for energy conversion and storage studies.   We start with making free-standing poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) films with a thickness >50 μm by vacuum filtration, which then are used in electrochemical production of hydrogen peroxide (H2O2) in a H-cell. Due to some drawbacks listed above, we shifted our focus to flow cells. The cathodic generation of H2O2 is combined with oxygen evolution reaction (OER) using nickel (II) oxide (NiO) to explore the possibility of using a polymer material in a flow cell environment. This flow cell system could reach a faradaic efficiency of 80% and the system loss is analyzed from different angles. However, the OER is kinetically sluggish and would need precious catalysts to drive the reaction. Instead of turning to precious catalysts, we proposed to replace the OER in the device with the oxidation of a water-soluble organic molecule oxidation, 4,5-dihydroxy-1,3-benzenedisulfonic acid disodium salt monohydrate (tiron/BQDS). The tiron oxidation is fast and does not need a catalyst. The tiron transport phenomena are investigated and we find that migration—a less recognized player—has a big role in regulating tiron transport. The last part of the thesis introduces a biomass-based membrane made from cellulose for a tiron-based aqueous organic redox flow battery. The environmentally friendly nanocellulose membranes display reduced crossover of quinone redox couples, higher discharge capacity, and better reusability than the commercial fluoropolymer Nafion™ 115 membranes.   We hope the present thesis, which deals with various aspects of flow cells from organic material design to system transport phenomena, will stimulate more people to work on this fascinating topic, paving the way for electrification of everything by tunable and sustainable organic molecules.