Data_Sheet_1_Catalyst-Inspired Charge Carriers for High Energy Density Redox Flow Batteries.PDF

Dataset UNKNOWN
Popov, Ivan A.; Davis, Benjamin L.; Mukundan, Rangachary; Batista, Enrique R.; Yang, Ping;
(2019)
  • Publisher: Figshare
  • Related identifiers: doi: 10.3389/fphy.2018.00141.s001
  • Subject: catalyst-inspired | Applied Physics | Computational Physics | redox flow batteries (RFB) | Biophysics | Fe-complex | Astrophysics | Plasma Physics | Solar System, Solar Physics, Planets and Exoplanets | redox potentials | Condensed Matter Physics | density functional theory | computational modeling
    • FOR: 30699 Physical Chemistry not elsewhere classified | 20501 Classical and Physical Optics | 20109 Space and Solar Physics | 20203 Particle Physics | 20504 Photonics, Optoelectronics and Optical Communications | 40108 Tropospheric and Stratospheric Physics | 20106 High Energy Astrophysics; Cosmic Rays | 30304 Physical Chemistry of Materials | 40106 Cloud Physics | 20399 Classical Physics not elsewhere classified | 20499 Condensed Matter Physics not elsewhere classified | 10599 Mathematical Physics not elsewhere classified | 20699 Quantum Physics not elsewhere classified | 20107 Mesospheric, Ionospheric and Magnetospheric Physics

<p>We introduce a theoretical design approach aiming at improving energy density of redox flow batteries (RFBs) via the utilization of redox non-innocent ligands capable of stabilizing a metal center in a wide range of oxidation states. Our findings suggest that this pr... View more
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