Reflection and absorption of millimeter waves by thin absorbing films.

Reflection, transmission, and absorption of mm-waves by thin absorbing films were determined at two therapeutic frequencies: 42. 25 and 53.57 GHz. Thin filter strips saturated with distilled water or an alcohol-water solution were used as absorbing samples of different thicknesses. The dependence of the power reflection coefficient R(d) on film thickness (d) was not monotonic. R(d) passed through a pronounced maximum before reaching its steady-state level [R(infinity)]. Similarly, absorption, A(d), passed two maximums with one minimum between them, before reaching its steady-state level [A(infinity)]. At 42.25 GHz, A(d) was compared with absorption in a semi-infinite water medium at a depth d. When d < 0.3 mm, absorption by the film increased: at d = 0.1 mm the absorption ratio for the thin layer sample and the semi-infinite medium was 3.2, while at d = 0.05 mm it increased up to 5.8. Calculations based on Fresnel equations for flat thin layers adequately described the dependence of the reflection, transmission, and absorption on d and allowed the determination of the refractive index (n), dielectric constant (epsilon), and penetration depth (delta) of the absorbing medium for various frequencies. For water samples, epsilon was found to be 12.4-19.3j, delta = 0.49 mm at 42.25 GHz, and epsilon = 9.0-19.5j, delta = 0.36 mm at 53.57 GHz. The calculated power density distribution within the film was strongly dependent on d. The measurements and calculations have shown that the reflection and absorption of mm-waves by thin absorbing layers can significantly differ from the reflection and absorption in similar semi-infinite media. The difference in reflection, absorption, and power density distribution in films, as compared to semi-infinite media, are caused by multiple internal reflections from the film boundaries. That is why, when using thin phantoms and thin biological samples, the specifics of the interaction of mm-waves with thin films should be taken into account.

[1]  M C Ziskin,et al.  Medical application of millimetre waves. , 1998, QJM : monthly journal of the Association of Physicians.

[2]  Shiro Takashima,et al.  Electrical Properties of Biopolymers and Membranes , 1989 .

[3]  Max Born,et al.  Principles of optics - electromagnetic theory of propagation, interference and diffraction of light (7. ed.) , 1999 .

[4]  Herbert P. Neff Basic electromagnetic fields , 1981 .

[5]  Om P. Gandhi,et al.  Effect of Millimeter-Wave Irradiation on Growth of Saccharomyces cerevisiae , 1986, IEEE Transactions on Biomedical Engineering.

[6]  O P Gandhi,et al.  Some basic properties of biological tissues for potential biomedical applications of millimeter waves. , 1983, The Journal of microwave power.

[7]  E.P. Khizhnyak,et al.  Heating patterns in biological tissue phantoms caused by millimeter wave electromagnetic irradiation , 1994, IEEE Transactions on Biomedical Engineering.

[8]  M. Ziskin,et al.  Temperature oscillations in liquid media caused by continuous (nonmodulated) millimeter wavelength electromagnetic irradiation. , 1996, Bioelectromagnetics.

[9]  O. Gandhi,et al.  Millimeter wave absorption spectra of biological samples. , 1980, Bioelectromagnetics.

[10]  M. Ziskin,et al.  Millimeter Waves at 25 mw/cm2 have No Effect on Hydroxyl Radical-Dependent Lipid Peroxidation , 1998 .

[11]  O. Gandhi,et al.  Absorption of Millimeter Waves by Human Beings and its Biological Implications , 1986 .

[12]  K. Foster,et al.  RF-field interactions with biological systems: Electrical properties and biophysical mechanisms , 1980, Proceedings of the IEEE.

[13]  O. Gandhi,et al.  Substitution Method for Swept-Frequency Measurements of Dielectric Properties at Microwave Frequencies , 1982 .