Effect of ionic contaminants on dielectric dispersion and relaxation processes over static permittivity frequency region in neat liquid poly(ethylene glycol)

“…In the nanoconfined, low-ionic limit where λ exceeds the confinement length, dielectric responses of pure water remain important but are controversial due to the myriad dielectric quantities invoked: ϵ ⊥ ( z ), the corresponding parallel profile ϵ ∥ ( z ), ϵ r , the tensor elements of the dielectric matrix ϵ̅ ⊥ and ϵ̅ ∥ , and what we will call the ion–ion dielectric constant ϵ ii which governs ion–ion interactions. ϵ r can be measured. , ϵ ⊥ ( z ) and ϵ̅ ⊥ are related to capacitance measurements under slit-like nanoconfinement; from this and other experiments, water is inferred to exhibit strongly reduced ϵ̅ ⊥ under confinement. Low ϵ r or ϵ̅ ⊥ values appear empirically correlated with enhanced ion-adsorption/aggregation, but the basis of this approach has been strongly questioned .…”

“…ϵ r can be measured. 7,8 ϵ ⊥ (z) and ϵ ̅ ⊥ are related to capacitance measurements 14 under slit-like nanoconfinement; from this and other 13 experiments, water is inferred to exhibit strongly reduced ϵ ̅ ⊥ under confinement. Low ϵ r or ϵ ̅ ⊥ values appear empirically correlated with enhanced ionadsorption/aggregation, 5 but the basis of this approach has been strongly questioned.…”

“…Dielectric properties in confined liquids are widely acknowledged to govern chemical reactions, ion adsorption at interfaces, contact-ion-pairing, and colloid interactions in electrolytes relevant to physical chemistry, energy storage, and geochemistry. − In the presence of ions, infinities naturally arise in the zero-frequency (ω = 0) limit in unconfined electrolytes (Figure a). This is well-known in low-frequency (ω < 1 kHz) measurements , but its consequences at the atomic length-scale have seldom been examined in modern modeling and experimental efforts, which tend to focus on the MHz to GHz frequency range where water and ionic solutions exhibit a finite plateau in dielectric response. For example, current molecular dynamics (MD) simulations of nano- to microsecond trajectory lengths, by definition, cannot reach frequencies far below 1 kHz, obscuring the divergences in unconfined aqueous media.…”

Finding Infinities in Nanoconfined Geothermal Electrolyte Static Dielectric Properties and Implications on Ion Adsorption/Pairing

“…In the nanoconfined, low-ionic limit where λ exceeds the confinement length, dielectric responses of pure water remain important but are controversial due to the myriad dielectric quantities invoked: ϵ ⊥ ( z ), the corresponding parallel profile ϵ ∥ ( z ), ϵ r , the tensor elements of the dielectric matrix ϵ̅ ⊥ and ϵ̅ ∥ , and what we will call the ion–ion dielectric constant ϵ ii which governs ion–ion interactions. ϵ r can be measured. , ϵ ⊥ ( z ) and ϵ̅ ⊥ are related to capacitance measurements under slit-like nanoconfinement; from this and other experiments, water is inferred to exhibit strongly reduced ϵ̅ ⊥ under confinement. Low ϵ r or ϵ̅ ⊥ values appear empirically correlated with enhanced ion-adsorption/aggregation, but the basis of this approach has been strongly questioned .…”

“…ϵ r can be measured. 7,8 ϵ ⊥ (z) and ϵ ̅ ⊥ are related to capacitance measurements 14 under slit-like nanoconfinement; from this and other 13 experiments, water is inferred to exhibit strongly reduced ϵ ̅ ⊥ under confinement. Low ϵ r or ϵ ̅ ⊥ values appear empirically correlated with enhanced ionadsorption/aggregation, 5 but the basis of this approach has been strongly questioned.…”

“…Dielectric properties in confined liquids are widely acknowledged to govern chemical reactions, ion adsorption at interfaces, contact-ion-pairing, and colloid interactions in electrolytes relevant to physical chemistry, energy storage, and geochemistry. − In the presence of ions, infinities naturally arise in the zero-frequency (ω = 0) limit in unconfined electrolytes (Figure a). This is well-known in low-frequency (ω < 1 kHz) measurements , but its consequences at the atomic length-scale have seldom been examined in modern modeling and experimental efforts, which tend to focus on the MHz to GHz frequency range where water and ionic solutions exhibit a finite plateau in dielectric response. For example, current molecular dynamics (MD) simulations of nano- to microsecond trajectory lengths, by definition, cannot reach frequencies far below 1 kHz, obscuring the divergences in unconfined aqueous media.…”

Finding Infinities in Nanoconfined Geothermal Electrolyte Static Dielectric Properties and Implications on Ion Adsorption/Pairing

Comparative study of alkali (Li, Rb and Cs) halide doped KDP single crystals

Electrode polarization and ionic conduction relaxation in n-Hexanol and DMF Mixtures at 303.15 K: insights into molecular dynamics