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Effects of a Nanophase-Separated Structure on Mechanical Properties and Proton Conductivity of Acid-Infiltrated Block Polymer Electrolyte Membranes under Non-Humidification.

Takato KajitaHaruka TanakaYumiko OhtsukaTsuyoshi OridoAtsushi TakanoHiroyuki IwamotoAlbert MufundirwaHideto ImaiAtsushi Noro
Published in: ACS omega (2022)
Acid-infiltrated block polymer electrolyte membranes adopting a spherical or lamellar nanophase-separated structure were prepared by infiltrating sulfuric acid (H 2 SO 4 ) into polystyrene- b -poly(4-vinylpyridine)- b -polystyrene (S-P-S) triblock copolymers to investigate the effects of its nanophase-separated structure on mechanical properties and proton conductivities under non-humidification. Lamellae-forming S-P-S/H 2 SO 4 membranes with a continuous hard phase generally exhibited higher tensile strength than sphere-forming S-P-S/H 2 SO 4 membranes with a discontinuous hard phase even if the same amount of Sa was infiltrated into each neat S-P-S film. Meanwhile, the conductivities of lamellae-forming S-P-S/H 2 SO 4 membranes under non-humidification were comparable or superior to those of sphere-forming S-P-S/H 2 SO 4 membranes, even though they were infiltrated by the same weight fraction of H 2 SO 4 . This result is attributed to the conductivities of S-P-S/H 2 SO 4 membranes being greatly influenced by the acid/base stoichiometry associated with acid-base complex formation rather than the nanophase-separated structure adopted in the membranes. Namely, there are more free H 2 SO 4 moieties that can release free protons contributing to the conductivity in lamellae-forming S-P-S/H 2 SO 4 membranes than sphere-forming S-P-S/H 2 SO 4 , even when the same amount of H 2 SO 4 was infiltrated into the S-P-S.
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