Auditory Effects of Microwave Radiation

James C. Lin

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English

Springer Nature Switzerland AG
20 August 2021

Biomedical engineering; Wave mechanics (vibration & acoustics); Biophysics; Neurosciences; Microwave technology

This book examines the human auditory effects of exposure to directed beams of high-power microwave pulses, which research results have shown can cause a cascade of health events when aimed at a human subject or the subject’s head. The book details multidisciplinary investigations using physical theories and models, physiological events and phenomena, and computer analysis and simulation. Coverage includes brain anatomy and physiology, dosimetry of microwave power deposition, microwave auditory effect, interaction mechanisms, shock/pressure wave induction, Havana syndrome, and application in microwave thermoacoustic tomography (MTT). The book will be welcomed by scientists, academics, health professionals, government officials, and practicing biomedical engineers as an important contribution to the continuing study of the effects of microwave pulse absorption on humans.

By: James C. Lin
Imprint: Springer Nature Switzerland AG
Country of Publication: Switzerland
Edition: 1st ed. 2021
Dimensions: Height: 235mm, Width: 155mm,
Weight: 711g
ISBN: 9783030645434
ISBN 10: 3030645436
Pages: 348
Publication Date: 20 August 2021
Audience: Professional and scholarly , Undergraduate
Format: Hardback
Publisher's Status: Active

AUDITORY EFFECTS OF MICROWAVE RADIATION James C. Lin University of Illinois at Chicago Chapters 1. Introduction 1.1 Electromagnetic Radiation and Spectrum 1.2 Microwave Technology and Applications 1.2.1 Microwave Diathermy 1.2.2 Microwave Ablation Therapy 1.2.3 Hyperthermia Treatment of Cancer 1.2.4 Microwave Ovens 1.2.5 Magnetic Resonance Imaging 1.2.6 Modern Microwave Radars 1.2 Auditory Effects from Pulsed Microwave Exposure 1.3 A Diplomatic Affair 1.4 Organizing Principle of the Book References 2. Principles of Microwave and RF Exposure 2.1 The Maxwell Equations 2.2 The Wave Equation 2.3 Boundary Conditions at Material Interfaces 2.4 Energy Storage and Power flow 2.5 Plane Waves and Far-Zone Field 2.6 Polarization and Propagation of Plane Waves 2.6.1. Plane Waves in Free Space 2.6.2. Plane Waves in Lossy or Biological Media 2.7 Reflection and Transmission at Interfaces 2.8 Refraction of Microwave and RF Radiation 2.9 Radiation of Electromagnetic Energy 2.9.1 The Short Dipole Antenna 2.9.2. Near-Zone Radiation 2.9.3 Antenna Receiving Characteristics References 3. Brain Anatomy and Auditory Physiology 3.1 Anatomy and Physiology of the Human Brain 3.2 The Human Auditory System 3.2.1 External and Middle Ears 3.2.2 The Inner Ear 3.2.3 Cochlear Mechanical Activity and Transduction 3.2.4 Cochlear Microphonics and Electrical Potentials 3.2.5 Action Potentials of the Auditory Nerve 3.2.6 Central Auditory Nuclei and Pathways 3.3 Perception of Sound and Pressure 3.3.1 Transmission of Sound Pressure 3.3.2 Loudness and Pitch 3.3.3 Sound Localization 3.3.4 Masking Effect 3.3.5 Deafness and Hearing Loss 3.3.6 Hearing Acuity and Audiometry References 4. Microwave Property of Biological Materials 4.1 Frequency Dependence of Dielectric Permittivity 4.2 Relaxation Processes 4.2.1 Low-Loss Dielectric Materials 4.2.2. Lossy Dielectrics at Low Frequencies 4.2.3. Biological Materials 4.3 Temperature Dependence of Dielectric Properties 4.4 Measured Tissue and Modeled Permittivity Data 4.4.1 Permittivity of Water 4.4.2 Measured Tissue Permittivity Data 4.4.3 Debye Modeling of Tissue Permittivity Data 4.4.4 Temperature Dependence of Measured Tissue Permittivity 4.4.5 Dielectric Permittivity at Low Temperatures References 5. Dosimetry and Microwave Absorption 5.1 Dosimetric Quantities and Units 5.2 Boundary of Planar Interfaces 5.3 Multiple Tissue Layers 5.4 Influence of Orientation and Polarization 5.5 Spheroidal Head Models 5.6 Absorption in Anatomical Models 5.6.1 The Visible Human Anatomical Model 5.6.2 Family of Anatomical Computer Models 5.7 Computing SAR in Anatomical Models 5.7.1 The FDTD Algorithm 5.7.2 SAR in Anatomical Human Head in MRI or Near-Zone Exposures 5.7.3 SAR in Anatomical Body Exposed to Plane Waves References 6. The Microwave Auditory Effect 6.1 A Historical Perspective 6.2 Psychophysical Studies in Humans 6.2.1 Microwave Pulses at 1245 MHz 6.2.2 Microwaves Pulses at 2450 MHz 6.2.3 Microwaves Pulses at 3000 MHz 6.3 Threshold Power Density for Human Perception 6.3.1 Field Tests of Adult Humans with Normal Hearing 6.3.2 Laboratory Study of Human Adults with Normal Hearing 6.4 Loudness of Human Perception 6.5 Behavioral Study in Animals 6.5.1 Discriminative Control of Appetitive Behavior 6.5.2 Pulsed Microwave as A Cue in Avoidance Conditioning 6.6 Neurophysiological Study in Animals 6.6.1 Brainstem Evoked Response 6.6.2 Primary Auditory Cortex 6.6.3 Central Auditory Nuclei 6.6.4 The Eighth Cranial Auditory Nerve 6.6.5 Cochlear Round Window 6.6.6 Cochlear Microphonics 6.6.7 Brainstem Nuclei Ablations on Auditory Evoked Responses 6.6.8 Manipulation of Middle and Outer Ears on BER Potentials 6.6.9 Brain Tissue as Site of Interaction 6.7 Animal Thresholds, Noise, and BER Potentials 6.7.1 Eletrophysiologic Threshold Determination in Animals 6.7.2 Effect of Ambient Noise Level 6.7.3 Microwave BER Recordings References 7. Mechanisms of Microwave to Acoustic Energy Conversion 7.1 Site of Microwave to Acoustic Energy Transduction 7.2 Possible Mechanisms of Interaction 7.2.1 Radiation Pressure 7.2.2 Electrostrictive Force 7.2.3 Thermoelastic Stress 7.3 Analysis of Possible Transduction Mechanisms 7.3.1 Computation of Radiation Pressure 7.3.2 Electrostrictive Force Calculation 7.3.3 Thermoelastic Pressure Generation 7.4 Biophysical Properties of Biological Materials 7.5 Comparison of Possible Transduction Mechanisms References 8. Thermoelastic Pressure Waves in Canonical Head Models 8.1 Analytic Formulation of Microwave Induced Thermoelastic Pressure 8.1.1 Microwave Absorption 8.1.2 Temperature Elevation 8.1.3 Thermoelastic Equation of Motion 8.2 Pressure Wave in Stress-Free Brain Spheres 8.2.1 Thermoelastic Pressure for Ft (t) = 1 8.2.2 Rectangular Pulse-Induced Pressure in Stress-Free Sphere 8.3 Pressure in Brain Spheres with Constrained Surface 8.3.1 Induced Thermoelastic Pressure for Ft (t) = 1 8.3.2 Rectangular Pulse-Induced Pressure for Constrain Surfaces 8.4 Other Absorption Patterns and Pulse Waveforms 8.5 Calculated and Measured Frequencies for Spherical Head Models 8.5.1 Theoretically Predicted Frequency of Acoustic Pressure Waves 8.5.2 Measured Frequency in Spherical Head Models 8.6 Calculated Pressure Amplitude and Displacement 8.6.1 Stress-Free Boundary 8.6.2 Constrained Boundary 8.6.3 Pressure Wave Dependence on Pulse Width and Pulse Shape 8.7 Pressure Wave Measurements in Animal Heads 8.7.1 Pressure Sensing in Animal Head and Frequency Analysis 8.7.2 Comparison of Predicted and Measured Sound Frequency 8.7.3 Pressure Wave Propagation Measurement in Cat’s Head 8.8 Comparison of Predicted and Measured Response Characteristics in Human and Animal Heads 8.8.1 Dependence of Response Amplitude on Microwave Pulse Width References 9. Computer Simulation of Pressure Waves in Anatomic Head Models 9.1 FDTD Formulation for Microwave Thermoelastic Pressure Waves 9.1.1 Maxwell’s Electromagnetic Equations 9.1.2 Biological Heat Transfer Equation 9.1.3 Thermoelastic Equation of Motion 9.1.4 Modulated Rectangular Pulse Functions 9.2 Sound Pressure Waves Induced by RF Pulses in MRI Systems 9.2.1 Homogeneous Spherical Head Model 9.2.2 Anatomical Head Model 9.2.3 Thermoelastic Pressure Waves in Anatomical Head Model 9.2.4 MRI Safety Guidelines 9.2.5 Human Subjects Inside MRI RF Head Coils 9.3 Pressure Waves in Human Heads from Far Field Exposure 9.4 Whole-Body Model Exposed to Plane Waves References 10. Applied Aspects and Applications 10.1 Microwave Thermoacoustic Tomography and Imaging 10.1.1 Microwave Thermoacoustic Imaging 10.1.2 Microwave Thermoacoustic Tomography 10.1.3 Further Investigations of MTT 10.1.4 Recent Developments in MTT 10.1.5 Other MTT Application Domains 10.2 Reports of Diplomatic Personnel’s Sonic Attacks 10.3 Directed Messaging and Mind Control 10.4 Microwave Signal at the Moscow Embassy References Index

Dr. James C. Lin is Professor Emeritus at the University of Illinois in Chicago (UIC), where he has served as Head of the Bioengineering Department, Director of the Robotics and Automation Laboratory, Director of Special Projects in the College of Engineering, and Professor in the departments of Electrical Engineering, Bioengineering, Physiology, and Biophysics. He is a Fellow of AAAS, AIMBE, and URSI, and a Life Fellow of IEEE. He held a NSC Research Chair and was an IEEE-EMBS distinguished lecturer. He is a recipient of the d’Arsonval Medal from the Bioelectromagnetics Society (BEMS), IEEE EMC Transactions Prize Paper Award, IEEE COMAR Recognition Award, and CAPAMA Outstanding Leadership and Service Awards. He served for two years as a member of the U.S. President’s Committee for National Medal of Science. He has authored or edited 13 books, authored 380+ book chapters and articles in journals and magazines, and made 280+ conference presentations. In addition to fundamental scientific contributions to electromagnetics in biology and medicine, he has pioneered several medical applications of RF and microwave energies, including invention of minimally invasive microwave ablation treatment for cardiac arrhythmia and noncontact and noninvasive microwave sensing of physiological signatures and vital signs. Dr. Lin has chaired several international conferences sponsored by the IEEE, BEMS, URSI, and ICST (founding chairman of Wireless Mobile Communication and Healthcare - MobiHealth). He has been Editor-in-Chief of the Bioelectromagnetics journal since 2006 and has served as guest editor of several journals. He is a member of Sigma Xi, Phi Tau Phi, Tau Beta Pi, and Golden Key honorary societies. He also served on numerous advisory committees and panels for the U.S. Congress, Office of the U.S. President, National Academy of Sciences, National Research Council, National Science Foundation, National Institutes of Health, Marconi Foundation, and the World Health Organization.