Thermally Stable Super Ionic Conductor from Carbon Sphere Oxide

Abstract: A highly stable proton conductor has been developed from carbon sphere oxide (CSO). Carbon sphere (CS) generated from sucrose was oxidized successfully to CSO using Hummers' graphite oxidation technique. At room temperature and 90 % relative humidity, the proton conductivity of thin layer CSO on microsized comb electrode was found to be 8.7×10(-3)  S cm(-1) , which is higher than that for a similar graphene oxide (GO) sample (3.4×10(-3)  S cm(-1) ). The activation energy (Ea ) of 0.258 eV suggests that the pro… Show more

“…The carbon‐based solid electrolytes for fuel cells, sensors, chemical filters, etc. are desirable for their low cost, high thermal, mechanical and chemical stability, ease of fabrication, and nontoxic nature . The ionic movement within GO interlayers in an aqueous solution was first reported by Raidongia et al., who also presented the possibility of a GO‐based solid electrolyte .…”

Superionic Conductivity in Hybrid of 3‐Hydroxypropanesulfonic Acid and Graphene Oxide

“…The carbon‐based solid electrolytes for fuel cells, sensors, chemical filters, etc. are desirable for their low cost, high thermal, mechanical and chemical stability, ease of fabrication, and nontoxic nature . The ionic movement within GO interlayers in an aqueous solution was first reported by Raidongia et al., who also presented the possibility of a GO‐based solid electrolyte .…”

Superionic Conductivity in Hybrid of 3‐Hydroxypropanesulfonic Acid and Graphene Oxide

“…Modied Hummers' method was used to prepare GO from bulk graphite powder. 10 A 1000 mL beaker containing 1.0 g graphite powder was placed in an ice bath. Furthermore, 48 mL H 2 SO 4 (97%) and 1.0 g of NaNO 3 was carefully added and mixed homogeneously using a magnetic stirrer for 30 min.…”

Role of hydrophilic groups in acid intercalated graphene oxide as a superionic conductor

“…This agrees with a previous report that showed that use of a milder reduction environment mainly leads to the reduction of epoxy sites . The reactivity of these groups is likely due to strain associated with bond angle distortion away from regular tetrahedral . The decomposition of epoxy groups creates some holes and oxygen vacancies, which are responsible for p‐type semiconducting behaviour.…”

Photoreduction Dependent p‐ and n‐Type Semiconducting Field‐Effect Transistor Properties in Undoped Reduced Graphene Oxide