Composite polymer electrolytes based on the low crosslinked copolymer of linear and hyperbranched polyurethanes

Abstract: Low crosslinked copolymer of linear and hyperbranched polyurethane (CHPU) was prepared, and the ionic conductivities and thermal properties of the composite polymer electrolytes composed of CHPU and LiClO 4 were investigated. The FTIR and Raman spectra analysis indicated that the polyurethane copolymer could dissolve more lithium salt than the corresponding polymer electrolytes of the non crosslinked hyperbranched polyurethane, and showed higher conductivities. At salt concentration EO/Li ¼ 4, the electrolyte … Show more

“…79 The ionic conductivities and thermal characteristics of composite polymer electrolytes made of PU-based polymer and LiClO 4 were explored using a low crosslinked copolymer of linear and hyperbranched polyurethane (CHPU). 95 According to the FTIR and Raman spectra, the PU copolymer could dissolve more lithium salt than the similar polymer electrolytes of the noncrosslinked hyperbranched PU, thus exhibiting greater conductivity. At 25 °C, the electrolyte CHPU30-LiClO 4 obtained its maximum conductivity of 1.51105 S cm −1 at a salt concentration with ethylene number/Li + ratio of 4.…”

“…At 25 °C, the electrolyte CHPU30-LiClO 4 obtained its maximum conductivity of 1.51105 S cm −1 at a salt concentration with ethylene number/Li + ratio of 4. 95 Crosslinking is a promising strategy for improving the mechanical strength of a polymer electrolyte, in addition to reducing PEO crystallization and providing high temperature dimensional stability. Also, crosslinked polymer can absorb more lithium salt compared to the non-crosslinked polymer and hence increases the conductivity value.…”

“…According to the FTIR and Raman spectra, the PU copolymer could dissolve more lithium salt than the similar polymer electrolytes of the non‐crosslinked hyperbranched PU, thus exhibiting greater conductivity. At 25 °C, the electrolyte CHPU30‐LiClO 4 obtained its maximum conductivity of 1.51105 S cm −1 at a salt concentration with ethylene number/Li + ratio of 4 95 …”

Polyurethane‐based polymer electrolyte for lithium ion batteries: a review

“…79 The ionic conductivities and thermal characteristics of composite polymer electrolytes made of PU-based polymer and LiClO 4 were explored using a low crosslinked copolymer of linear and hyperbranched polyurethane (CHPU). 95 According to the FTIR and Raman spectra, the PU copolymer could dissolve more lithium salt than the similar polymer electrolytes of the noncrosslinked hyperbranched PU, thus exhibiting greater conductivity. At 25 °C, the electrolyte CHPU30-LiClO 4 obtained its maximum conductivity of 1.51105 S cm −1 at a salt concentration with ethylene number/Li + ratio of 4.…”

“…At 25 °C, the electrolyte CHPU30-LiClO 4 obtained its maximum conductivity of 1.51105 S cm −1 at a salt concentration with ethylene number/Li + ratio of 4. 95 Crosslinking is a promising strategy for improving the mechanical strength of a polymer electrolyte, in addition to reducing PEO crystallization and providing high temperature dimensional stability. Also, crosslinked polymer can absorb more lithium salt compared to the non-crosslinked polymer and hence increases the conductivity value.…”

“…According to the FTIR and Raman spectra, the PU copolymer could dissolve more lithium salt than the similar polymer electrolytes of the non‐crosslinked hyperbranched PU, thus exhibiting greater conductivity. At 25 °C, the electrolyte CHPU30‐LiClO 4 obtained its maximum conductivity of 1.51105 S cm −1 at a salt concentration with ethylene number/Li + ratio of 4 95 …”

Polyurethane‐based polymer electrolyte for lithium ion batteries: a review