Abstract
Low cost, scalability, potentially high energy density, and sustainability make organic magnesium (ion) battery (OMB) technologies a promising alternative to other rechargeable metal-ion battery solutions such as secondary lithium ion batteries (LIB). However, most reported OMB cathode materials have limited performance due to, in particular, low voltages often smaller than 2 V vs. Mg2+/Mg and/or low specific capacities compared to other competing battery technologies, e.g., LIB or sodium ion batteries. While the structural diversity of organic compounds and the large amount of possible chemical modifications potentially allow designing high voltage/capacity OMB electrode materials, the large search space requires efficient exploration of potential molecular-based electrode materials by rational design strategies on an atomistic scale. By means of density functional theory (DFT) calculations, we provide insights into possible strategies to increase the voltage by changes in electronic states via functionalization, by strain, and by coordination environment of Mg cations. A systematic analysis of these effects is performed on explanatory systems derived from selected prototypical building blocks: five- and six-membered rings with redox-active groups. We demonstrate that voltage increase by direct bandstructure modulation is limited, that strain on the molecular scale can in principle be used to modulate the voltage curve and that the coordination/chemical environment can play an important role to increase the voltage in OMB. We propose molecular structures that could provide voltages for Mg insertion in excess of 3 V.
Highlights
The development of smart grids, renewable energy sources (Dunn et al, 2011) and electro-mobility (Lu et al, 2013) are just a few fields that demand improved electric energy storage technologies
It was shown in several studies that the energies of the lowest unoccupied molecular orbital (LUMO) significantly correlate to the voltage achieved with materials operating by reduction as the electron from the attached alkali atom, e.g., Li, will occupy the LUMO of the molecule (Burkhardt et al, 2013; Liang et al, 2013; Kim et al, 2015b, 2016; Lüder et al, 2017a)
When one uses in this model the LUMO energy before molecular reduction, we address this model as static
Summary
The development of smart grids, renewable energy sources (Dunn et al, 2011) and electro-mobility (Lu et al, 2013) are just a few fields that demand improved electric energy storage technologies. Secondary metal ion battery technologies are at the forefront of current electrical energy storage research as they can provide high energy density, be used in mobile as well as stationary/large scale applications and could last thousands of charge-discharge. The search for highperformance electrode materials extends over a huge search space of materials, and much effort was made and will continue to be necessary to explore it further to find new materials leading to improved battery performance (Mohtadi and Mizuno, 2014; Yabuuchi et al, 2014; Kim et al, 2015a; Wang et al, 2015; Muench et al, 2016; Mauger et al, 2017; Leisegang et al, 2019)
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