Solid-state NMR studies of the crystalline and amorphous domains within PEO and PEO: LiTf systems

• Published in: Solid state nuclear magnetic resonance Vol. 31; no. 4; pp. 184 - 192
• Main Authors: Wickham, Jason R., Mason, Rachel N., Rice, Charles V.
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier Inc 01.07.2007
• Subjects: Amorphous; CP-MAS; Crystalline; Crystallization; Lithium; Magnetic Resonance Spectroscopy; PEO; Polyethylene Glycols; REDOR; Salts; Solid polymer electrolytes; T 1ρ; Amorphous; Crystalline; REDOR; T 1 ρ; PEO; Solid polymer electrolytes; CP-MAS
• ISSN: 0926-2040; 1527-3326
• DOI: 10.1016/j.ssnmr.2007.05.001

Solid polymer electrolytes (SPEs) contain amorphous and crystalline regions, each of which have unique contributions to the 13C NMR spectrum. Understanding and assigning the 13C NMR signals are vital to interpreting the NMR data collected for each phase. The 13C CPMAS solid-state NMR spectrum of poly(ethylene oxide), a common polymer electrolyte host material, has superimposed broad and narrow components. Previously, the narrow component has been assigned to the amorphous region and the broad component to the crystalline PEO fraction. These assignments for pure PEO have been applied to various PEO:salt systems. Using lithium triflate salt dissolved in PEO, we revisit the spectral assignments and discover that the narrow component is due to crystalline PEO:LiTf component, which is reversed from the previous pure PEO assignment. This paradigm shift is based on data collected from a 100% crystalline PEO:LiTf with a 3:1 oxygen:lithium ratio sample, which exhibited only the narrow peak. For dilute electrolytes, such as 20:1 PEO:LiTf, the 13C CPMAS spectra contain the narrow peak superimposed on a broad peak as seen with pure PEO. As dilute electrolytes are heterogeneous with crystalline and amorphous regions of both pure PEO and PEO:LiTf complex, peak assignments for pure PEO and PEO:LiTf are important. Thus, we reexamine the previous assignment for pure PEO using samples of pure powdered PEO, thermally treated pure powdered PEO, and a thin film PEO cast from an acetonitrile solution. With these different samples, we observed the growth of the narrow peak under conditions that favor crystallization. Therefore, for pure PEO, we have reassigned the narrow peak to the crystalline region and the broad peak to the amorphous region. In light of our observations, previous NMR studies of pure PEO and PEO SPEs should be reinvestigated. We also use rotational echo double resonance (REDOR) to study the 20:1 PEO:LiTf created from 2 and 100 kDa PEO. We find that the lithium environment is similar in the respective microcrystalline domains. However, the 100 kDa samples have a larger fraction of pure crystalline PEO.