Sub-THz complex dielectric constants of smectite clay thin samples with Na$^{+}$/Ca$^{++}$-ions

TL;DR

This study measures the complex dielectric constants of oriented smectite clay samples with Na$^{+}$ and Ca$^{++}$ ions at sub-terahertz frequencies, revealing ion-dependent dielectric and conductive properties relevant for electromagnetic characterization.

Contribution

The paper introduces a novel open cavity resonator technique for characterizing the dielectric properties of thin clay samples at 100-165 GHz, highlighting ion-specific effects.

Findings

Real dielectric constant is constant across frequencies but differs between Na$^{+}$ and Ca$^{++}$-clays.

Electrical conductivity increases with frequency, especially for Na$^{+}$-clays above 110 GHz.

Dielectric dispersion depends on ionic strength and interlayer zeta potential.

Abstract

We implement a technique to characterize the electromagnetic properties at frequencies 100 to 165 GHz (3 cm$^{-1}$ to 4.95 cm$^{-1}$) of oriented smectite samples using an open cavity resonator connected to a sub-millimeter wave VNA (Vector Network Analyzer). We measured dielectric constants perpendicular to the bedding plane on oriented Na$^{+}$ and Ca$^{++}$-ion stabilized smectite samples deposited on a glass slide at ambient laboratory conditions (room temperature and room light). The clay layer is much thinner ($\sim$ 30 $\mu$m) than the glass substrate ($\sim$ 2.18 mm). The real part of dielectric constant, $\epsilon_{re}$, is essentially constant over this frequency range but is larger in Na$^{+}$- than in Ca$^{++}$-ion infused clay. The total electrical conductivity (associated with the imaginary part of dielectric constant, $\epsilon_{im}$) of both samples increases monotonically at lower frequencies ($<$ 110 GHz), but shows rapid increase for Na$^{+}$ ions in the regime $>$ 110 GHz. The dispersion of the samples display a dependence on the ionic strength in the clay interlayers, i.e., $\zeta$-potential in the Stern layers.