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2.5 Electrical permittivity characterization of aqueous solutions

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The instrumentation and methods used to obtain electrical permittivity measurements of aqueous solutions across the frequency range 200 MHz – 3 GHz are given. Deionized water and saline aqueous solutions are used as examples.

Introduction

Permittivity (in the framework of electromagnetics) is a fundamental material property that describes how a material will affect, and be affected by, a time-varying electromagnetic field. The parameters of permittivity are often treated as a complex function of the applied electromagnetic field as complex numbers allow for the expression of magnitude and phase. The fundamental equation for the complex permittivity of a substance (ε s ) is given by [link] , where ε’ and ε’’ are the real and imaginary components, respectively, ω is the radial frequency (rad/s) and can be easily converted to frequency (Hertz, Hz) using [link] .

ε s = ε ' ( ω ) '' ( ω ) size 12{ε rSub { size 8{s} } =ε' \( ω \) - iε"''" \( ω \) } {}
ω = 2πf size 12{ω=2πf} {}

Specifically, the real and imaginary parameters defined within the complex permittivity equation describe how a material will store electromagnetic energy and dissipate that energy as heat. The processes that influence the response of a material to a time-varying electromagnetic field are frequency dependent and are generally classified as either ionic, dipolar, vibrational, or electronic in nature. These processes are highlighted as a function of frequency in [link] . Ionic processes refer to the general case of a charged ion moving back and forth in response a time-varying electric field, whilst dipolar processes correspond to the ‘flipping’ and ‘twisting’ of molecules, which have a permanent electric dipole moment such as that seen with a water molecule in a microwave oven. Examples of vibrational processes include molecular vibrations (e.g. symmetric and asymmetric) and associated vibrational-rotation states that are Infrared (IR) active. Electronic processes include optical and ultra-violet (UV) absorption and scattering phenomenon seen across the UV-visible range.

A dielectric permittivity spectrum over a wide range of frequencies. ε′ and ε″ denote the real and the imaginary part of the permittivity, respectively. Various processes are labeled on the image: ionic and dipolar relaxation, and atomic and electronic resonances at higher energies.

The most common relationship scientists that have with permittivity is through the concept of relative permittivity: the permittivity of a material relative to vacuum permittivity. Also known as the dielectric constant, the relative permittivity (ε r ) is given by [link] , where ε s is the permittivity of the substance and ε 0 is the permittivity of a vacuum (ε 0 = 8.85 x 10 -12 Farads/m). Although relative permittivity is in fact dynamic and a function of frequency, the dielectric constants are most often expressed for low frequency electric fields where the electric field is essential static in nature. [link] depicts the dielectric constants for a range of materials.

ε r = ε s / ε 0 size 12{ε rSub { size 8{r} } =ε rSub { size 8{s} } /ε rSub { size 8{0} } } {}
Relative permittivities of various materials under static (i.e. non time-varying) electric fields.
Material Relative Permittivity
Vacuum 1 (by definition)
Air 1.00058986
Polytetrafluoroethylene (PTFE, Teflon) 2.1
Paper 3.85
Diamond 5.5-10
Methanol 30
Water 80.1
Titanium dioxide (TiO 2 ) 86-173
Strontium titanate (SrTiO 3 ) 310
Barium titanate (BaTiO 3 ) 1,200-10,000
Calcium copper titanate (CaCu 3 Ti 4 O 12 ) >250,000

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Source:  OpenStax, Physical methods in chemistry and nano science. OpenStax CNX. May 05, 2015 Download for free at http://legacy.cnx.org/content/col10699/1.21
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