Das metallurgische und elektrische Verhalten von Koks, insbesondere von Erzkoks, unter den realen Bedingungen des elektrischen Niederschachtofens

“…For the measurements displayed, specific resistance decreases with increasing particle size; for the electrode KS15‐X4, a resistivity of 43.4 Ωcm and for KS 15–X10, a resistivity of 21.2 Ωcm is measured. As the conductivity of graphite is very high (= 1 − 1·10 5 S cm −1 (parallel to the graphene planes in a single crystal), the specific resistance of the electrodes results from contact resistances between the particles . An electrode can be assumed as a resistant network and the number of contacts, and, thus, contact resistances determine the electric conductivity of the investigated composite electrodes .…”

“…As the conductivity of graphite is very high (¼ 1 À 1·10 5 S cm À1 (parallel to the graphene planes in a single crystal) [19] , the specific resistance of the electrodes results from contact resistances between the particles. [20] An electrode can be assumed as a resistant network and the number of contacts, and, thus, contact resistances determine the electric conductivity of the investigated composite electrodes. [21] The number of active material particles in the electrode coating decreases with increasing particle size and, thus, decreasing number of contacts.…”

Designing Graphite‐Based Positive Electrodes and Their Properties in Dual‐Ion Batteries Using Particle Size‐Adjusted Active Materials

“…For the measurements displayed, specific resistance decreases with increasing particle size; for the electrode KS15‐X4, a resistivity of 43.4 Ωcm and for KS 15–X10, a resistivity of 21.2 Ωcm is measured. As the conductivity of graphite is very high (= 1 − 1·10 5 S cm −1 (parallel to the graphene planes in a single crystal), the specific resistance of the electrodes results from contact resistances between the particles . An electrode can be assumed as a resistant network and the number of contacts, and, thus, contact resistances determine the electric conductivity of the investigated composite electrodes .…”

“…As the conductivity of graphite is very high (¼ 1 À 1·10 5 S cm À1 (parallel to the graphene planes in a single crystal) [19] , the specific resistance of the electrodes results from contact resistances between the particles. [20] An electrode can be assumed as a resistant network and the number of contacts, and, thus, contact resistances determine the electric conductivity of the investigated composite electrodes. [21] The number of active material particles in the electrode coating decreases with increasing particle size and, thus, decreasing number of contacts.…”

Designing Graphite‐Based Positive Electrodes and Their Properties in Dual‐Ion Batteries Using Particle Size‐Adjusted Active Materials