• Media type: E-Article
  • Title: Reactive Spray Drying Approach Towards rGO As Matrix Material for the Cathode of Li-S Batteries
  • Contributor: Müllner, Sebastian; Roth, Christina
  • Published: The Electrochemical Society, 2022
  • Published in: ECS Meeting Abstracts, MA2022-01 (2022) 2, Seite 296-296
  • Language: Not determined
  • DOI: 10.1149/ma2022-012296mtgabs
  • ISSN: 2151-2043
  • Keywords: General Medicine
  • Origination:
  • Footnote:
  • Description: Lithium-sulfur batteries represent a promising alternative to the classical Li-ion technology, particularly due to the high specific energy density combined with the good environmental sustainability of sulfur. Compared to state-of-the-art cathode materials for Li-ion batteries (LiB), which usually contain cobalt and/or manganese, sulfur is less toxic and much more abundant [1]. Additionally, the theoretical capacity of 1.675 mAh g-1 is more than eight times higher than typical cathode materials as Lithium-Nickel-Mangan-Cobalt-Oxide (NMC), Lithium-Cobalt-Oxide (LCO) or Lithium-Iron-Phosphate (LFP) [1,2]. One of the main challenges of sulfur is the so-called “shuttle effect” [1,3]. During lithiation soluble intermediates (polysulfides) migrate to the anode side, further react and precipitate, resulting in a continuous loss of active material and capacity. Next to that, the poor electrical conductivity (5∙10-30 S cm-1) does not allow the utilization of pure sulfur as cathode material [1]. To improve the low conductivity, carbon-containing composites have been proposed as cathode material for Li-S batteries for several decades. One possible carbon matrix material is reduced graphene oxide (rGO) [4]. The reduced form of partially oxidized graphite (graphite oxide; GO) is a graphene-like material with high potential for a scale-up to mass production. In our group, we have developed a new synthesis method to rapidly reduce GO using a reactive spray drying technique, where most functional groups can be removed from GO within seconds. The rapid thermal processing leads to a reduced and exfoliated rGO, which still contains small amounts of epoxy groups within the carbon lattice. These remaining oxygen atoms influence the conjugated π-bonds of the graphene-like matrix and thus change the polarity of the surface. A thermal post-treatment for 2 h in Ar/H2 can further reduce the remaining functional groups leading to a highly non-polar surface. It is assumed that oxygen-containing groups (e.g. epoxy and hydroxy) result in a varying adsorption behavior of the polysulfides, affecting the unwanted “shuttle effect” and thus influencing the electrochemical performance [5]. Here, we show the impact of remaining functional groups in rGO on the electrochemical performance of S-rGO composites as cathode material vs. Li/Li+. We compare untreated GO to reactive spray dried and additionally (thermally) post-treated rGO. Furthermore, we analyze the composites in terms of asymmetric and symmetric bonding vibrations as well as crystallinity using FT-IR, RAMAN and XRD. [1] Baikalov, N. et al., Frontiers Energy Research 2020, 8, 207 [2] Su, Y.-S. et al., Nature Communications 2013, 4, 2985 [3] Ren, W. et al., Energy Storage Materials 2019, 23, 707-732 [4] Shastri, M. et al., Ceramics International 2021, 47, 10, B, 14790-14797 [5] Ji, L. et al., Journal of the American Chemical Society 2011, 133, 18522-18525
  • Access State: Open Access