Borehole acoustic waves propagate through formations and boreholes in complex ways depending on the properties of the media. An understanding of basic wave propagation concepts is important for modern sonic logging technology. Waves include compressional waves, shear waves, head waves, Stoneley waves that travel along interfaces, and other modes. Properties of the formations, such as velocity and permeability, affect the behavior of the different wave types.
1. The document discusses interference and diffraction of waves, specifically light waves. Interference occurs when two waves meet and either constructively or destructively interfere. Constructive interference occurs when crest meets crest or trough meets trough, increasing amplitude. Destructive interference is when crest meets trough, canceling the waves' effects.
2. Conditions for interference include using monochromatic, coherent sources that are close together. Interference of light waves creates bright and dark bands called interference fringes. Reflection is when a wave bounces off a surface. The angle of incidence equals the angle of reflection. Reflection of light follows these laws.
This document discusses refraction of waves, including light waves and water waves. It defines refraction as a change in direction of wave propagation when moving between two different media due to a change in speed. It describes how the wavelength, frequency, and speed of waves change when moving from deep to shallow water or vice versa. Specifically, it notes that wavelength decreases and speed decreases for waves moving from deep to shallow water.
This document discusses the reflection of waves, including:
- The law of reflection states that the angle of incidence equals the angle of reflection, and the wavelength and frequency of the incident and reflected waves are equal.
- Reflection of waves can be observed using a ripple tank, where a vibrating motor creates waves that reflect off barriers.
- Examples are given of plane and circular wave reflections off flat and curved surfaces.
The document appears to be a chapter about sound from a textbook or study guide. It consists of multiple choice questions about various properties and behaviors of sound. Key points covered include:
- The types of sound waves humans can and cannot hear (infrasonic and ultrasonic).
- How sound travels through air via compressions and rarefactions.
- That the speed of sound varies with temperature but not amplitude or frequency.
- Common phenomena involving sound waves, such as reflection, refraction, resonance, interference, and beats.
- Applications of sound waves including echo location, medical ultrasound, and noise cancellation.
Here are the key points of comparison between incident and reflected waves:
i. Angle of incidence (i) = Angle of reflection (r)
ii. Wavelength (λ), frequency (f) and speed (v) remain the same.
iii. Direction of propagation - Reflected waves propagate in the opposite direction to the incident waves.
iv. Amplitude may decrease slightly due to absorption at the boundary. Otherwise, the wave remains the same.
v. Phase may be reversed depending on the type of boundary - either in phase or 180° out of phase.
vi. For perfect reflection from a smooth surface, the reflected wavefronts are parallel to the incident wavefronts.
The document discusses several optics concepts including interference, diffraction, dispersion of light, the electromagnetic spectrum, reflection, refraction, mirrors, lenses, and important formulas. Interference can be constructive or destructive. Diffraction refers to how waves bend around obstacles. Dispersion of light occurs when the index of refraction varies with wavelength. Reflection and refraction describe how waves interact with surfaces and change speed when passing between substances. Mirrors and lenses have focal points determined by their curvature and distance from the lens.
This document summarizes key concepts about wave properties. It defines waves as a movement of energy through space and time that requires a medium to travel through. It describes the characteristics of frequency, period, speed, wavelength, and how they are related. It differentiates between transverse and longitudinal waves, and provides examples of each. It also explains several phenomena waves can undergo, including interference, reflection, refraction, diffraction, polarization, and standing waves.
This document contains multiple choice questions about waves and vibrations. It covers topics like the definitions of vibration, wave, frequency, period, wavelength, amplitude. It also discusses characteristics of different types of waves like transverse waves, longitudinal waves, standing waves. Concepts like wave interference, Doppler effect, shock waves, and sonic booms are also introduced. The document tests the reader's understanding of these fundamental wave concepts through a series of related multiple choice questions.
1. The document discusses interference and diffraction of waves, specifically light waves. Interference occurs when two waves meet and either constructively or destructively interfere. Constructive interference occurs when crest meets crest or trough meets trough, increasing amplitude. Destructive interference is when crest meets trough, canceling the waves' effects.
2. Conditions for interference include using monochromatic, coherent sources that are close together. Interference of light waves creates bright and dark bands called interference fringes. Reflection is when a wave bounces off a surface. The angle of incidence equals the angle of reflection. Reflection of light follows these laws.
This document discusses refraction of waves, including light waves and water waves. It defines refraction as a change in direction of wave propagation when moving between two different media due to a change in speed. It describes how the wavelength, frequency, and speed of waves change when moving from deep to shallow water or vice versa. Specifically, it notes that wavelength decreases and speed decreases for waves moving from deep to shallow water.
This document discusses the reflection of waves, including:
- The law of reflection states that the angle of incidence equals the angle of reflection, and the wavelength and frequency of the incident and reflected waves are equal.
- Reflection of waves can be observed using a ripple tank, where a vibrating motor creates waves that reflect off barriers.
- Examples are given of plane and circular wave reflections off flat and curved surfaces.
The document appears to be a chapter about sound from a textbook or study guide. It consists of multiple choice questions about various properties and behaviors of sound. Key points covered include:
- The types of sound waves humans can and cannot hear (infrasonic and ultrasonic).
- How sound travels through air via compressions and rarefactions.
- That the speed of sound varies with temperature but not amplitude or frequency.
- Common phenomena involving sound waves, such as reflection, refraction, resonance, interference, and beats.
- Applications of sound waves including echo location, medical ultrasound, and noise cancellation.
Here are the key points of comparison between incident and reflected waves:
i. Angle of incidence (i) = Angle of reflection (r)
ii. Wavelength (λ), frequency (f) and speed (v) remain the same.
iii. Direction of propagation - Reflected waves propagate in the opposite direction to the incident waves.
iv. Amplitude may decrease slightly due to absorption at the boundary. Otherwise, the wave remains the same.
v. Phase may be reversed depending on the type of boundary - either in phase or 180° out of phase.
vi. For perfect reflection from a smooth surface, the reflected wavefronts are parallel to the incident wavefronts.
The document discusses several optics concepts including interference, diffraction, dispersion of light, the electromagnetic spectrum, reflection, refraction, mirrors, lenses, and important formulas. Interference can be constructive or destructive. Diffraction refers to how waves bend around obstacles. Dispersion of light occurs when the index of refraction varies with wavelength. Reflection and refraction describe how waves interact with surfaces and change speed when passing between substances. Mirrors and lenses have focal points determined by their curvature and distance from the lens.
This document summarizes key concepts about wave properties. It defines waves as a movement of energy through space and time that requires a medium to travel through. It describes the characteristics of frequency, period, speed, wavelength, and how they are related. It differentiates between transverse and longitudinal waves, and provides examples of each. It also explains several phenomena waves can undergo, including interference, reflection, refraction, diffraction, polarization, and standing waves.
This document contains multiple choice questions about waves and vibrations. It covers topics like the definitions of vibration, wave, frequency, period, wavelength, amplitude. It also discusses characteristics of different types of waves like transverse waves, longitudinal waves, standing waves. Concepts like wave interference, Doppler effect, shock waves, and sonic booms are also introduced. The document tests the reader's understanding of these fundamental wave concepts through a series of related multiple choice questions.
This document discusses waves and their properties. It begins by introducing different types of waves like transverse waves, longitudinal waves, and electromagnetic waves. It then defines key wave properties such as amplitude, wavelength, frequency, period, wave speed, and how these properties are related. The document also discusses concepts like wave reflection, refraction, diffraction, interference and examples of sound waves and electromagnetic waves. It concludes by providing examples of resonant systems and how damping affects oscillations.
This document discusses key concepts about sound waves, including:
1) Sound waves create regions of higher and lower pressure as they pass through a medium, compressing and stretching it.
2) The speed of sound depends on the medium and can be calculated using the bulk modulus and density of the medium.
3) A sound wave's wavelength depends on its frequency and speed, with the wavelength being shorter in denser mediums like water compared to air at the same frequency.
4) While wavelength can vary, the speed of sound is determined solely by properties of the medium like temperature, and is not affected by changes in frequency or wavelength.
Waves transfer energy through a medium without transferring matter. There are two main types of waves: transverse waves, where the medium's particles move perpendicular to the wave's direction; and longitudinal waves, where particles move parallel. Characteristics like wavelength, frequency, amplitude, and speed define a wave's properties. Energy is transferred through reflections, where waves bounce back at the same angle they arrive. Reflections can be partial or total, depending on the boundary material.
The document discusses key concepts in acoustics including sound reflection, absorption, diffraction, standing waves, reverberation time, room modes, and the inverse square law. It explains how reverberation time can be calculated using the Sabine equation and lists common absorption coefficients for various materials. Finally, it defines binaural hearing and the differences between mono and stereo audio formats.
When a wave crosses a boundary between two media, it is partially transmitted and partially reflected. The amount depends on the boundary - a hard boundary reflects the wave out of phase, while a soft boundary reflects it in phase. Reflection follows the law that the angle of incidence equals the angle of reflection. Refraction occurs when a wave crosses into a medium with a different wave speed, causing it to change direction according to Snell's law. Diffraction spreads waves out when they pass through an opening or obstacle. Superposition combines overlapping waves constructively or destructively based on their phase difference.
This document provides information about waves and wave phenomena. It discusses the key characteristics of waves like frequency, wavelength, amplitude, and speed. It explains different types of waves including transverse, longitudinal, and standing waves. The document also covers wave behavior at boundaries, interference, reflection, the Doppler effect, and more. Concepts are defined and illustrated with diagrams. The document is intended as a comprehensive reference on the physics of waves and wave motion.
Waves can interact in several ways when they overlap in space. Constructive interference occurs when wave amplitudes add, increasing the overall amplitude. Destructive interference happens when wave amplitudes subtract, decreasing the overall amplitude. Reflection is when a wave bounces off a surface, obeying the law of reflection. Refraction is when a wave changes speed and direction as it enters a new medium. Standing waves form from the interference of traveling waves reflecting back on themselves, creating nodes and antinodes. Resonance amplifies vibrations at an object's natural frequency.
This document discusses key concepts in ultrasound imaging including wave interference and diffraction, beam formation using planar and focused transducers, factors affecting resolution, and harmonic imaging techniques. It provides examples of calculations for beam properties like near-field length and beam width at focus. Non-linear wave propagation effects at high pressures are described along with their use in harmonic imaging to reduce noise and improve depth penetration. Key intensity metrics used for ultrasound safety are also defined.
1. Interference occurs when two waves meet and their displacements are combined according to the principle of superposition.
2. There are two types of interference: constructive and destructive. Constructive interference occurs when displacements are in the same direction, increasing amplitude. Destructive interference occurs when displacements are in opposite directions, decreasing or canceling amplitude.
3. Young's double-slit experiment demonstrates wave interference using a laser and double slit. It produces bright and dark fringes resulting from constructive and destructive interference of the light waves.
This document discusses various seismic methods and concepts. It begins by defining the critical angle and Snell's law for refraction seismology. It then distinguishes between the reflection and refraction seismic methods. The refraction method involves keeping the source fixed while spacing receivers further from the source, resulting in an x-t plot. Various seismic arrivals are described like direct waves, reflections, and refractions. Factors that affect seismic waves like attenuation and energy partitioning are also summarized. The document concludes by covering seismic sources, instruments, and refraction seismic methods.
The document is a presentation on architectural acoustics submitted by Riyas MS. It discusses key topics in sound including:
- Generation of sound which occurs when an object vibrates and causes pressure waves in the air.
- Propagation of sound which moves through a medium like air or water via sound waves. The speed depends on the properties of the medium.
- Reception of sound which involves the perception of sound waves by the brain after vibration of a membrane like a drum.
- Other characteristics of sound discussed include frequency, wavelength, velocity, intensity, the inverse square law, and the decibel unit used to measure sound intensity.
Diffraction is the bending of light, water, and sound waves when passing through an opening or around an obstacle. It occurs when the wavelength is comparable to or greater than the size of the opening/obstacle and causes the waves to spread out beyond them. Examples given include light diffracting through small openings and forming diffraction gratings, water waves diffracting around boats in harbors, and sound diffracting around corners allowing communication between adjacent rooms. Diffraction is demonstrated using ripple tanks and exploited by owls to communicate over long distances through forests.
Waves can interfere when they overlap in space. Constructive interference occurs when wave amplitudes add, increasing the overall amplitude. Destructive interference occurs when wave amplitudes subtract, decreasing the overall amplitude. When a wave encounters a boundary, it can be reflected. The angle of reflection is equal to the angle of incidence. Refraction occurs when a wave passes from one medium to another of different density, changing the wave's direction. Standing waves occur when a traveling wave is reflected back on itself, forming areas of maximum and minimum displacement.
1.3 refraction Fizik SPM - Pembiasan GelombangCikgu Fizik
Refraction occurs when a wave passes from one medium to another with a different speed. Water waves, light waves, and sound waves all experience refraction. Water waves refract towards the normal when passing to shallower water and away from the normal when passing to deeper water. Light waves refract towards the normal when passing to an optically denser medium. Sound waves refract towards the normal when passing to a denser medium like carbon dioxide. Experiments show that refraction causes changes in the wavelength, speed, and direction of propagating waves.
The sound wave will travel faster through water than through air due to their different bulk moduli and densities. The speed of sound in water is 1483.24 m/s while in air it is 290.11 m/s. As a result, the travel time for the sound to reach the diver 100m below the surface (0.067s) will be less than the time for it to reach the shore horizontally through air (0.345s). Therefore, the diver will hear the sound first.
1. Sound is a longitudinal mechanical wave that propagates through a medium such as air or water by compressions and rarefactions which create regions of high and low pressure.
2. The document discusses several properties of sound waves including that frequency determines pitch, amplitude determines loudness, and speed depends on the properties of the medium.
3. Wave interference and phenomena like resonance, standing waves, and the Doppler effect are also covered as they relate to the nature and perception of sound waves.
The document discusses various topics related to petrophysics and elastic properties of rocks. It covers different acoustic logging tools including monopole, dipole, and quadrupole sources and the different wave modes they generate. It discusses concepts like attenuation, dispersion, and the measurement of compressional, shear and stoneley velocities from well logs. The document also covers calculating elastic properties of rocks like shear modulus, Poisson's ratio, bulk modulus from well log data, and applications of elastic properties in fracture analysis, pore pressure evaluation, and seismic modeling.
- The document discusses the wave theory of light proposed by Christian Huygens in 1679, which explained properties such as interference, diffraction, and polarization that Newton's particle theory could not.
- It describes the principles of coherence and superposition of waves, which are required for the interference of light. Coherent sources exhibit a predictable correlation in amplitude and phase. The principle of superposition states that the resultant displacement of overlapping waves is the algebraic sum of the individual displacements.
- Young's double-slit experiment is discussed as providing the first evidence of light interference. When light passes through two slits, the waves spread out and interfere with each other on the screen, creating bright and dark interference fr
This document discusses waves, sound, and music. It covers topics such as how sound is produced through vibration, the propagation of sound waves, and properties of sound like frequency, wavelength, and amplitude. It also discusses challenges in teaching these concepts, such as visualizing wave motion and representing waves graphically. Students will learn about longitudinal waves, wave interference, reflection, standing waves in instruments, and applications of sound including music, speech, sonar, and ultrasound. Resources are provided for further support and references.
Wave motion transfers energy from one place to another. There are two main types of waves: transverse waves where particles oscillate perpendicular to the wave direction, and longitudinal waves where particles oscillate parallel to the wave direction. Key wave properties include amplitude, wavelength, frequency, and phase. Waves can undergo various interactions including reflection, refraction, diffraction, interference, and superposition. Interference of waves leads to constructive and destructive interference patterns. Standing waves occur due to interference of waves traveling in opposite directions.
This document discusses waves and their properties. It begins by introducing different types of waves like transverse waves, longitudinal waves, and electromagnetic waves. It then defines key wave properties such as amplitude, wavelength, frequency, period, wave speed, and how these properties are related. The document also discusses concepts like wave reflection, refraction, diffraction, interference and examples of sound waves and electromagnetic waves. It concludes by providing examples of resonant systems and how damping affects oscillations.
This document discusses key concepts about sound waves, including:
1) Sound waves create regions of higher and lower pressure as they pass through a medium, compressing and stretching it.
2) The speed of sound depends on the medium and can be calculated using the bulk modulus and density of the medium.
3) A sound wave's wavelength depends on its frequency and speed, with the wavelength being shorter in denser mediums like water compared to air at the same frequency.
4) While wavelength can vary, the speed of sound is determined solely by properties of the medium like temperature, and is not affected by changes in frequency or wavelength.
Waves transfer energy through a medium without transferring matter. There are two main types of waves: transverse waves, where the medium's particles move perpendicular to the wave's direction; and longitudinal waves, where particles move parallel. Characteristics like wavelength, frequency, amplitude, and speed define a wave's properties. Energy is transferred through reflections, where waves bounce back at the same angle they arrive. Reflections can be partial or total, depending on the boundary material.
The document discusses key concepts in acoustics including sound reflection, absorption, diffraction, standing waves, reverberation time, room modes, and the inverse square law. It explains how reverberation time can be calculated using the Sabine equation and lists common absorption coefficients for various materials. Finally, it defines binaural hearing and the differences between mono and stereo audio formats.
When a wave crosses a boundary between two media, it is partially transmitted and partially reflected. The amount depends on the boundary - a hard boundary reflects the wave out of phase, while a soft boundary reflects it in phase. Reflection follows the law that the angle of incidence equals the angle of reflection. Refraction occurs when a wave crosses into a medium with a different wave speed, causing it to change direction according to Snell's law. Diffraction spreads waves out when they pass through an opening or obstacle. Superposition combines overlapping waves constructively or destructively based on their phase difference.
This document provides information about waves and wave phenomena. It discusses the key characteristics of waves like frequency, wavelength, amplitude, and speed. It explains different types of waves including transverse, longitudinal, and standing waves. The document also covers wave behavior at boundaries, interference, reflection, the Doppler effect, and more. Concepts are defined and illustrated with diagrams. The document is intended as a comprehensive reference on the physics of waves and wave motion.
Waves can interact in several ways when they overlap in space. Constructive interference occurs when wave amplitudes add, increasing the overall amplitude. Destructive interference happens when wave amplitudes subtract, decreasing the overall amplitude. Reflection is when a wave bounces off a surface, obeying the law of reflection. Refraction is when a wave changes speed and direction as it enters a new medium. Standing waves form from the interference of traveling waves reflecting back on themselves, creating nodes and antinodes. Resonance amplifies vibrations at an object's natural frequency.
This document discusses key concepts in ultrasound imaging including wave interference and diffraction, beam formation using planar and focused transducers, factors affecting resolution, and harmonic imaging techniques. It provides examples of calculations for beam properties like near-field length and beam width at focus. Non-linear wave propagation effects at high pressures are described along with their use in harmonic imaging to reduce noise and improve depth penetration. Key intensity metrics used for ultrasound safety are also defined.
1. Interference occurs when two waves meet and their displacements are combined according to the principle of superposition.
2. There are two types of interference: constructive and destructive. Constructive interference occurs when displacements are in the same direction, increasing amplitude. Destructive interference occurs when displacements are in opposite directions, decreasing or canceling amplitude.
3. Young's double-slit experiment demonstrates wave interference using a laser and double slit. It produces bright and dark fringes resulting from constructive and destructive interference of the light waves.
This document discusses various seismic methods and concepts. It begins by defining the critical angle and Snell's law for refraction seismology. It then distinguishes between the reflection and refraction seismic methods. The refraction method involves keeping the source fixed while spacing receivers further from the source, resulting in an x-t plot. Various seismic arrivals are described like direct waves, reflections, and refractions. Factors that affect seismic waves like attenuation and energy partitioning are also summarized. The document concludes by covering seismic sources, instruments, and refraction seismic methods.
The document is a presentation on architectural acoustics submitted by Riyas MS. It discusses key topics in sound including:
- Generation of sound which occurs when an object vibrates and causes pressure waves in the air.
- Propagation of sound which moves through a medium like air or water via sound waves. The speed depends on the properties of the medium.
- Reception of sound which involves the perception of sound waves by the brain after vibration of a membrane like a drum.
- Other characteristics of sound discussed include frequency, wavelength, velocity, intensity, the inverse square law, and the decibel unit used to measure sound intensity.
Diffraction is the bending of light, water, and sound waves when passing through an opening or around an obstacle. It occurs when the wavelength is comparable to or greater than the size of the opening/obstacle and causes the waves to spread out beyond them. Examples given include light diffracting through small openings and forming diffraction gratings, water waves diffracting around boats in harbors, and sound diffracting around corners allowing communication between adjacent rooms. Diffraction is demonstrated using ripple tanks and exploited by owls to communicate over long distances through forests.
Waves can interfere when they overlap in space. Constructive interference occurs when wave amplitudes add, increasing the overall amplitude. Destructive interference occurs when wave amplitudes subtract, decreasing the overall amplitude. When a wave encounters a boundary, it can be reflected. The angle of reflection is equal to the angle of incidence. Refraction occurs when a wave passes from one medium to another of different density, changing the wave's direction. Standing waves occur when a traveling wave is reflected back on itself, forming areas of maximum and minimum displacement.
1.3 refraction Fizik SPM - Pembiasan GelombangCikgu Fizik
Refraction occurs when a wave passes from one medium to another with a different speed. Water waves, light waves, and sound waves all experience refraction. Water waves refract towards the normal when passing to shallower water and away from the normal when passing to deeper water. Light waves refract towards the normal when passing to an optically denser medium. Sound waves refract towards the normal when passing to a denser medium like carbon dioxide. Experiments show that refraction causes changes in the wavelength, speed, and direction of propagating waves.
The sound wave will travel faster through water than through air due to their different bulk moduli and densities. The speed of sound in water is 1483.24 m/s while in air it is 290.11 m/s. As a result, the travel time for the sound to reach the diver 100m below the surface (0.067s) will be less than the time for it to reach the shore horizontally through air (0.345s). Therefore, the diver will hear the sound first.
1. Sound is a longitudinal mechanical wave that propagates through a medium such as air or water by compressions and rarefactions which create regions of high and low pressure.
2. The document discusses several properties of sound waves including that frequency determines pitch, amplitude determines loudness, and speed depends on the properties of the medium.
3. Wave interference and phenomena like resonance, standing waves, and the Doppler effect are also covered as they relate to the nature and perception of sound waves.
The document discusses various topics related to petrophysics and elastic properties of rocks. It covers different acoustic logging tools including monopole, dipole, and quadrupole sources and the different wave modes they generate. It discusses concepts like attenuation, dispersion, and the measurement of compressional, shear and stoneley velocities from well logs. The document also covers calculating elastic properties of rocks like shear modulus, Poisson's ratio, bulk modulus from well log data, and applications of elastic properties in fracture analysis, pore pressure evaluation, and seismic modeling.
- The document discusses the wave theory of light proposed by Christian Huygens in 1679, which explained properties such as interference, diffraction, and polarization that Newton's particle theory could not.
- It describes the principles of coherence and superposition of waves, which are required for the interference of light. Coherent sources exhibit a predictable correlation in amplitude and phase. The principle of superposition states that the resultant displacement of overlapping waves is the algebraic sum of the individual displacements.
- Young's double-slit experiment is discussed as providing the first evidence of light interference. When light passes through two slits, the waves spread out and interfere with each other on the screen, creating bright and dark interference fr
This document discusses waves, sound, and music. It covers topics such as how sound is produced through vibration, the propagation of sound waves, and properties of sound like frequency, wavelength, and amplitude. It also discusses challenges in teaching these concepts, such as visualizing wave motion and representing waves graphically. Students will learn about longitudinal waves, wave interference, reflection, standing waves in instruments, and applications of sound including music, speech, sonar, and ultrasound. Resources are provided for further support and references.
Wave motion transfers energy from one place to another. There are two main types of waves: transverse waves where particles oscillate perpendicular to the wave direction, and longitudinal waves where particles oscillate parallel to the wave direction. Key wave properties include amplitude, wavelength, frequency, and phase. Waves can undergo various interactions including reflection, refraction, diffraction, interference, and superposition. Interference of waves leads to constructive and destructive interference patterns. Standing waves occur due to interference of waves traveling in opposite directions.
The document summarizes key aspects of different parts of the electromagnetic spectrum including radio waves, microwaves, infrared, visible light, ultraviolet, x-rays, and gamma rays. It also discusses properties that apply across the spectrum such as all waves traveling at the speed of light, interference and diffraction effects. Additionally, it covers topics in waves and optics including reflection, refraction, lenses, sound waves, and seismic waves.
The document discusses two-dimensional waves and their properties. It covers topics like reflection, refraction, diffraction and interference of water waves. Experiments using these wave properties can be demonstrated using a ripple tank, which allows visualization of wave behavior and measurement of wave characteristics like wavelength.
This document discusses properties of mechanical waves, including:
- Mechanical waves require a medium and examples are water and sound waves. Electromagnetic waves do not require a medium.
- A mechanical wave transfers energy through a medium. Water waves move outward from where a rock hits a pond.
- The speed of a wave depends on the medium, not the amplitude or size of the wave. Sound waves travel at the same speed regardless of volume.
- A wave's shape is typically sinusoidal and characterized by amplitude, wavelength, crest, and trough. The fundamental wave equation relates speed, frequency, and wavelength.
This document covers various characteristics of waves including:
1) All waves transmit energy, diffract, reflect, refract, and exhibit constructive and destructive interference.
2) Diffraction is the spreading out of waves as they pass through an opening, like sound waves spreading through a doorway.
3) Refraction occurs when waves change speed as they pass into a new medium, like water waves bending as they enter shallow water.
4) Pitch is a sound wave's frequency, determining if it is high or low. Pure tones have one frequency while complex tones have multiple frequencies.
5) When waves of slightly different frequencies overlap, beats occur and disappear when the sources are in tune.
1. Interference occurs when two waves meet while propagating along the same medium. This can result in constructive or destructive interference depending on whether the crests and troughs of the two waves coincide.
2. Young's experiment demonstrates interference using a double slit. An interference pattern of light and dark fringes is produced on a screen due to the superposition of light waves emerging from the two slits.
3. Young's formula describes the relationship between the interference pattern and the wavelength, distance between slits, and distance from the slits to the observation point. The distance between fringes is directly proportional to wavelength and distance from slits, and inversely proportional to the slit separation distance.
Waves can be transverse or longitudinal. Transverse waves have oscillations perpendicular to the direction of travel, while longitudinal waves have oscillations parallel to the direction of travel. The key parts of a wave include the wavelength, amplitude, period, frequency, and speed. The wavelength is the distance between two peaks or troughs, while the amplitude is the maximum displacement from equilibrium. Period is the time for one full oscillation, and frequency is the inverse of period. Wave speed can be calculated by dividing the wavelength by the period.
INTRODUCTION TO QUANTUM THEORY LIGHT AND ITS PRINCIPLES
The General Characteristics, Properties and Classification of Wave, The Nature of Light (Is that
wave? Or particle? Or Both?), Classical and Quantum Theory of Light
THE WAVE NATURE OF LIGHT
Huygens’s wave theory of light, Young’s Double Slits Experiment, and Electromagnetic waves
(Maxwell’s Electromagnetic theory of light)
PARTICLE NATURE OF LIGHT
Newton’s corpuscular theory of light and Black Body radiation, Photoelectric Effect, The
Compton Scattering Effect, X-ray and X-ray Diffraction, and The Davinson-Germer Electron
Diffraction Experiment
WAVE PARTICLE DUALITY
De-Broglie Wave length, Electron Double Slits Diffraction Experiment, and Electron
Microscope
A wave is a disturbance that travels through a medium from one location to another. There are two main types of waves: mechanical waves, which require a physical medium and can be either longitudinal or transverse; and electromagnetic waves like light, which do not require a medium. Mechanical waves involve particle motion parallel to the direction of the wave for longitudinal waves or perpendicular for transverse waves. Wave properties include amplitude, wavelength, frequency, and speed. Waves can interfere constructively or destructively depending on if peaks and troughs align.
Light waves superimpose each other and the redistribution of energy due to this can be observed in terms of well defined patterns of maxima and minima. Wherein, maxima refers to more energy and minima refers to less energy. Diffraction can also be called as interference in secondary wavelets.
This document discusses waves and their characteristics. It defines two main types of waves - mechanical waves which require a medium and transfer energy through vibrations of that medium, and electromagnetic waves which transfer energy through disturbances in electromagnetic fields. It describes key wave characteristics such as amplitude, wavelength, velocity, frequency, and period. It also defines different types of mechanical waves including longitudinal waves, transverse waves, and surface waves based on the direction of the medium's vibration relative to the wave pulse.
When waves encounter obstacles like slits, they diffract or bend around the edges. Diffraction can be explained by Huygens' principle, which says each point on a wavefront acts as a new source. For a single slit, the new wavefront shape is determined by combining spherical wavelets from points across the slit. There are two types of diffraction: Fresnel, where distances are finite, and Fraunhofer, where incident waves are plane waves. X-ray diffraction uses wavelengths comparable to atomic sizes to determine crystal and molecular structures.
1. Waves can transfer energy without transferring matter. The document discusses different types of waves including transverse, longitudinal, plane, and sound waves. It also covers key wave concepts such as amplitude, wavelength, frequency, speed, and direction of propagation.
2. The document discusses various wave phenomena including reflection, refraction, diffraction, and interference. Activities are suggested to observe and analyze these phenomena using tools like ripple tanks and computer simulations. Formulas related to speed, wavelength and frequency are also introduced.
3. The document covers additional topics related to waves and oscillations including standing waves, resonance, and applications to sound waves and the electromagnetic spectrum. Learning outcomes focus on describing, analyzing and solving problems involving different types
1. Wave mechanics was introduced by De Broglie in 1924 and is based on the idea that particles can be regarded as waves described by the Schrodinger wave equation.
2. Waves transfer energy but not matter. Different types of waves include mechanical, electromagnetic, and matter waves. Mechanical waves require a medium while electromagnetic waves do not.
3. The wavelength is the distance between two consecutive peaks or troughs of a wave. The velocity, wavelength, and frequency of a wave are related by the equation v = λf.
MAHARASHTRA STATE BOARD
CLASS XI AND XII
PHYSICS
CHAPTER 7
WAVE OPTICS
CONTENT:
Huygen's principle.
Huygen's principles & proof of laws of reflection/refraction.
Condition for construction & destruction of coherent waves.
Young's double slit experiment.
Modified Young's double slit experiment.
Intensity of light in Y.D.S.E.
Diffraction due to single slit.
Polarisation & doppler effect.
Wave optics deals with phenomena like interference and diffraction that cannot be explained by ray optics. Interference occurs when two coherent light waves superimpose, resulting in constructive and destructive interference patterns. Diffraction occurs when light passes through an opening and spreads out. A diffraction grating uses the diffraction of light from many parallel slits to separate white light into its spectrum. It produces bright interference bands at angles satisfying the grating equation, allowing precise wavelength measurement.
1. Borehole Acoustic Waves
Borehole acoustic waves may be as simple or as complex as the formations in
which they propagate. An understanding of wave-propagation basics is essential
for appreciation of modern sonic-logging technology.
Jakob B.U. Haldorsen Everyday sounds come from many sources. wavefront. This simple case also assumes the
David Linton Johnson Keyboards click, crickets chirp, telephones ring formation is homogeneous and isotropic, and
Tom Plona and people laugh. Understanding the informa- that the sonic tool itself has no other effect on
Bikash Sinha tion contained in these sounds is something wave propagation.1
Henri-Pierre Valero that most people do without thinking. For most, The 3D cylindrical setting of the wellbore
Kenneth Winkler
deciphering the sounds they hear is much more complicates this explanation, which can be
Ridgefield, Connecticut, USA
important than knowing what sound waves are simplified by examining a vertical plane through
For help in preparation of this article, thanks to Jeff Alford,
and how they travel. the axis of a vertical borehole. In the resulting 2D
Houston, Texas; and Andy Hawthorn and Don Williamson, However, for geoscientists and others who system, spherical wavefronts become circles and
Sugar Land, Texas.
must understand the information contained in propagate in one plane. In a 3D world, wave-
sound waves traveling in the Earth, it is essential fronts propagate everywhere outward from the
to know what sound waves are and how they source and surround the borehole symmetrically.
travel. This article reviews the basic types of In the 2D simplification, when the wavefront
acoustic sources and the sound waves that travel in the borehole mud meets the borehole wall, it
in rocks near a borehole. We also discuss the generates three new wavefronts. A reflected
effects that variations in rock properties have on wavefront returns toward the borehole center at
acoustic waves. speed Vm. Compressional, P-, and shear, S-, waves
The acoustic waves recorded by a sonic- are transmitted, or refracted, through the
logging tool depend on the energy source, the interface and travel in the formation at speeds Vp
path they take and the properties of the and Vs, respectively. In this simplest case of a
formation and the borehole. In wireline logging, hard, or fast, formation, Vp > Vs > Vm.
there are two primary types of sources, monopole Once the refracted P-wave becomes parallel
and dipole. A monopole transmitter emits energy to the borehole wall, it propagates along the
equally in every direction away from its center, borehole-formation interface at speed Vp, faster
while a dipole transmitter emits energy in a than the reflected borehole-fluid wave.
preferred direction. According to Huygens principle, every point on
From a monopole transmitter located in the an interface excited by a P-wave acts as a
center of the borehole, a spherical wavefront secondary source of P-waves in the borehole as
travels a short distance through the borehole well as P- and S-waves in the formation. The
fluid until it meets the borehole wall. Part of the combination of these secondary waves in the
energy is reflected back into the borehole, and borehole creates a new linear wavefront called a
part of the energy causes waves to propagate in head wave.2 This first head wave in the mud is
the formation (next page, top). The direction of known as the compressional head wave, and its
wave propagation is always perpendicular to the
34 Oilfield Review
2. 40 70 80 90 110 170
Shear
head wave
Compressional
head wave
> The first few moments of simplified wavefront propagation from a monopole transmitter in a fluid-filled borehole (blue) and a fast formation (tan). Both
media are assumed homogeneous and isotropic. Tool effects are neglected. Time progression is to the right. Numbers in the upper left corner correspond
to time in µs after the source has fired. Wavefronts in the mud are black, compressional wavefronts in the formation are blue, and shear wavefronts in the
formation are red. The compressional head wave can be seen at 90 µs, and the shear head wave can be seen at 170 µs.
arrival at the receivers is recorded as the P Another way of visualizing how P and S head
Borehole Formation
arrival. The P-wave takes longer to arrive at waves and body waves travel near the borehole is
receivers that are farther from the source. The through ray tracing. Strictly speaking, ray tracing
Refracted P
time difference between P arrivals divided by the is valid only when the wavelength is much
distance traveled is known as ∆t , or slowness, smaller than the diameter of the borehole, or Refracted S
and is the reciprocal of speed. This is the most when the wavefronts can be approximated as Reflected P
basic sonic-logging measurement.3 planes rather than spheres or cones. Most
The P-wave that continues into the formation borehole acoustic modes, especially those at low θ2
is known as a body wave, and travels on deeper frequencies, do not meet these conditions, but θ1 θs
into the formation unless a reflector sends it ray tracing can still be useful for visualization. A
back toward the borehole, at which time it is ray is simply a line perpendicular to a wavefront, θ1
called a reflected P-wave. Standard sonic logging showing the direction of travel. A raypath Incident P-wave
ignores reflected P-waves, but special applica- between two points indicates the fastest travel
tions, such as those described near the end of path. Changes in raypath occur at interfaces and Source
this article, take advantage of the extra follow Snell’s law, an equation that relates the Mud velocity, Vm P velocity, Vp > Vm
information contained in reflected P-waves. angles at which rays travel on either side of an S velocity, Vs
The behavior of refracted S-waves is similar interface to their wave speeds (right). Among
Sin θ1 = Sin θ2 = Sin θs
to that of refracted P-waves. When the refracted other things, Snell’s law explains the conditions Vm Vp Vs
S-wave becomes parallel to the borehole wall, it under which head waves form and why none form
propagates along the borehole-formation in slow formations. > Wavefront reflection and refraction at interfaces,
interface as a shear disturbance at speed Vs and Ray tracing is useful for understanding where and Snell’s law. θ1 is the angle of incident and
generates another head wave in the borehole waves travel and for modeling basics of sonic-tool reflected P-waves. θ2 is the angle of refracted
fluid. Its arrival at the receivers is recorded as design, such as determining the transmitter- P-waves. θs is the angle of refracted S-waves.
the S-wave. In this way, shear slowness of a fast receiver (TR) spacing that is required to ensure Vm is mud-wave velocity. Vp is P-wave velocity in
the formation, and Vs is S-wave velocity in the
formation can be measured by a tool surrounded that the formation path is faster than the direct formation. When the angle of refraction equals
by borehole fluid, even though S-waves cannot mud path for typical borehole sizes and 90°, a head wave is created.
propagate through the fluid. formation P and S velocities. This ensures that
In cases when the shear-wave speed is less the tool will measure formation properties rather
than the mud-wave speed—a situation known as than borehole-mud properties. Ray tracing also
1. A homogeneous formation is one with uniform velocity.
a slow formation—the shear wavefront in the helps describe the relationship between TR In other words, the velocity is independent of location.
formation never forms a right angle with the An isotropic formation is one with velocity independent
of direction of propagation.
borehole. No shear head wave develops in the 2. The head wave has a conical wavefront in 3D.
fluid. In both fast and slow formations, an S body 3. Slowness typically has units of µs/ft.
wave continues into the formation.
Spring 2006 35
3. same effect at a much smaller scale leads to
“ground roll” noise in surface seismic surveys.
In 1924, Stoneley looked at waves propa-
gating at the interface between two solids and
found a similar type of surface wave.5 The
particular case corresponding to a fluid-filled
borehole, that is, the interface between a solid
and a liquid, was described not by Stoneley, but
by Scholte.6 The waves traveling at the fluid-
borehole interface are nonetheless known as
Stoneley waves. In other areas of geophysics,
Receiver
such as marine seismic surveys, waves traveling
array
at a fluid-solid interface are called Scholte or
Scholte-Stoneley waves.7
A Stoneley wave appears in nearly every
monopole sonic log. Its speed is slower than the
shear- and mud-wave speeds, and it is slightly
dispersive, so different frequencies propagate at
different speeds.
The decay of Stoneley-wave amplitude with
Transmitter
distance from the interface is also frequency-
dependent; at high frequencies, the amplitude
decays rapidly with distance from the borehole
wall. However, at low frequencies—or at wave-
Condition Effect
Zone of Unaltered Receiver
alteration formation
> Ray tracing using Snell’s law to model raypaths. Here,
rays are traced through a formation that has radially
varying velocity in a zone of alteration. Velocity is lower
near the borehole and grows larger with distance, a Attenuated
situation that arises when drilling induces near-wellbore
damage. Rays traveling to the receivers nearest the Reflected
transmitter travel only through the altered zone (dark ture
c
brown), and rays traveling to distant receivers sense the Fra
velocity of the unaltered formation (light brown).
Permeable Attenuated
spacing and near-wellbore altered-zone thick- radiate into the formation. These are called leaky and slowed
formation down
ness and velocity contrast (above). In addition, modes, and propagate at speeds between P and S
ray tracing is used in inversion techniques such velocities. Leaky modes are dispersive, meaning
as tomographic reconstruction, which solves for their different frequency components travel at
slowness models given arrival-time information. different speeds. Stoneley
After the P and S head waves, the next waves wave
to arrive at the receivers from a monopole source Stoneley Waves
are the direct and reflected mud waves. These The last arrivals from a monopole source are
Transmitter
are followed by trapped modes and interface interface, or surface, waves. Surface waves were
waves that owe their existence to the cylindrical first suggested by Lord Rayleigh in 1885.4 He > The Stoneley wave, traveling at the interface
nature of the borehole. Trapped modes arise investigated the response at the planar surface of between the borehole and the formation. The
from multiple internal reflections inside the an elastic material in contact with a vacuum and Stoneley wave is dispersive and its particle
borehole. Wavefronts of particular wavelengths found that a wave propagated along the surface motion is symmetric about the borehole axis. At
bouncing between the walls of the borehole with particle motion that decreased in amplitude low frequencies, the Stoneley wave is sensitive
to formation permeability. Waves traveling past
interfere with each other constructively and with distance from the surface—a property permeable fractures and formations lose fluid,
produce a series of resonances, or normal modes. called evanescence. Rayleigh’s findings and viscous dissipation causes attenuation of
Trapped modes are not always seen on logs and predicted the existence of waves that propagate wave amplitude and an increase in wave
may be affected by borehole condition. In slow along the Earth’s surface and give rise to the slowness. At open fractures, Stoneley waves
are both reflected and attenuated. Red arrows
formations, trapped modes lose part of their devastating shaking caused by earthquakes. The in the center of the borehole symbolize
energy to the formation in the form of waves that Stoneley-wave amplitude.
36 Oilfield Review
4. Compressional Shear Stoneley
wave wave wave
13
12
11
10
9
Receiver number
8
7
6
5
4
3
2
1
0 1,000 3,000 5,000
Time, µs
> Typical waveforms from a monopole transmitter in a fast formation, showing compressional, shear
and Stoneley waves. The pink dashed lines are arrival times. A sonic-logging tool receiver array is
shown at left.
lengths comparable to the borehole diameter— All of the above waves propagate symmetri- P-, S- and Stoneley-wave arrival times can be
the Stoneley amplitude decays very little with cally up and down the borehole, and can be seen clearly, but often, data-processing
distance from the borehole wall. At sufficiently detected by monopole receivers—typically techniques are used to pick times accurately. The
low frequencies, the amplitude is nearly constant hydrophones. Hydrophones are sensitive to difference in arrival times divided by the
from one side of the borehole to the other, pressure changes in the borehole fluid, and have distance between receivers yields the slowness
creating what is known as a tube wave. An omnidirectional response, meaning that they for each mode. However, in many recordings,
example of a tube wave is the water-hammer respond equally to pressure changes from high noise levels, bad hole conditions or other
effect that can sometimes be heard in plumbing any direction. factors can cause these arrivals to be indistinct
pipes when flow is suddenly disrupted. Waveforms recorded at a given depth are or mixed with each other. In such cases, visual or
The low-frequency Stoneley wave is sensitive initially displayed as a time series from the array automated picking of arrival times fails to yield
to formation permeability. When the wave of receivers (above). In some recordings, the true slownesses.
encounters permeable fractures or formations,
the fluid vibrates relative to the solid, causing 4. Strutt JW, 3rd Baron Rayleigh: “On Waves Propagated 7. Bohlen T, Kugler S, Klein G and Theilen F: “Case History
Along the Plane Surface of an Elastic Solid,” Proceedings 1.5D Inversion of Lateral Variation of Scholte-Wave
viscous dissipation in these zones, which of the London Mathematical Society 17 (1885): 4. Dispersion,” Geophysics 69, no. 2 (March–April 2004):
attenuates the wave and slows it down (previous Rayleigh waves on the Earth’s surface have vertical 330–344.
and horizontal components of motion. Other surface 8. Winkler KW, Liu HL and Johnson DJ: “Permeability and
page, right). The reductions in Stoneley-wave waves discovered by A.E.H. Love have two horizontal Borehole Stoneley Waves: Comparison Between
energy level and velocity vary with wave motion components. Experiment and Theory,” Geophysics 54, no. 1
5. Stoneley R: “Elastic Waves at the Surface of Separation (January 1989): 66–75.
frequency. Stoneley-wave dispersion data over a
of Two Solids,” Proceedings of the Royal Society, 9. Hornby BE, Johnson DL, Winkler KW and Plumb RA:
wide bandwidth of frequencies can be inverted to Series A 106 (1924): 416–428. “Fracture Evaluation Using Reflected Stoneley Wave
estimate formation permeability.8 Open fractures 6. Scholte JG: “On the Large Displacements Commonly Arrivals,” Geophysics 54, no. 10 (October 1989):
Regarded as Caused by Love Waves and Similar 1274–1288.
can also cause Stoneley waves to reflect back Dispersive Surface Waves,” Proceedings of the
toward the transmitter. The ratio of reflected to Koninklijke Nederlanse Akademie van Wetenschappen
51 (1948): 533–543.
incident energy correlates with fracture
aperture, or openness. This technique for the
detection of permeable fractures works well in
hard formations.9
Spring 2006 37
5. Dipole Sources
STC Coherence
So far, the discussion has focused on waves
Waveforms from 3,764.89 ft generated by monopole sources, but for some
Compressional Shear Stoneley Slowness
wave wave wave applications, a different type of source is
40 µs/ft 340
13 required. For example, in slow formations, where
12 monopole sources cannot excite shear waves, a
11
10 dipole source can be effective. The dipole source
Waveform number
9 primarily excites flexural waves, along with
8
7 compressional and shear head waves. The motion
6 of a flexural wave along the borehole can be
5
4 thought of as similar to the disturbance that
3 travels up a tree when someone standing on the
2
1 ground shakes the tree trunk. The analogy works
1,000 2,000 3,000 4,000 5,000
better if the tree trunk is fixed at the top and has
Time, µs constant diameter.
3,760 Typically, a tool designed to generate flexural
300
waves will contain two dipole sources oriented
orthogonally along the tool X- and Y-axes. The
dipole transmitters are fired separately. First,
Slowness, µs/ft
the X-dipole is fired, and a flexural waveform is
200
recorded. Then, the Y-dipole is fired, and a
separate measurement is taken. The flexural
wave travels along the borehole in the plane of
100
the dipole source that generated it. The particle
motion of the flexural wave is perpendicular to
1,000 2,000 3,000 4,000 5,000 the direction of wave propagation, similar to
Time, µs
3,770
S-waves, and flexural-wave slowness is related to
S-wave slowness. Extracting S-wave slowness
from flexural-wave data is a multistep process.
> Slowness-time-coherence (STC) processing for monopole arrivals. Waveforms Flexural waves are dispersive, meaning their
at a given depth (top left) are scanned over time windows and over a range of slowness varies with frequency (below). In many
angles—called moveouts, which are related to slowness. When the signals on sets of flexural waveforms, it is possible to see
the waveforms within the window are best correlated, coherence is maximum.
An STC plot for that depth (bottom left) displays color-coded coherence in the the wave shape change across the receiver array
slowness-time plane, with maximum coherence in red. The coherence values as different frequency components propagate at
are projected onto a vertical strip along the slowness axis and then displayed different speeds. Because the wave shape
as a thin horizontal strip at the appropriate depth on the STC projection log
(right). A slowness log for each wave is generated by joining the coherence
maxima at all depths.
13
11
Waveform number
Slownesses can be estimated in a robust way corresponding to compressional, shear and 9
with minimal human intervention using a signal- Stoneley slownesses plotted for each depth
7
processing technique that looks for similarity— create a slowness log. The two dimensions of an
known mathematically as semblance, or STC plot are compressed into a single dimension 5
coherence—in waveforms across the receiver by projecting the coherence peaks onto the
array.10 The method starts with an assumed slowness axis. This vertical strip of color-coded 3
arrival time and slowness for each wave type and coherences, when plotted horizontally at the
1
searches the set of waveforms for the time and appropriate depth, forms an element of an STC-
1,000 3,500 6,000
slowness that maximize coherence. The graph of projection log, a standard sonic-logging output.
Time, μs
coherence for different values of slowness and The slowness of each mode is plotted on top of
> Flexural-mode waveforms, showing a change
time is called a slowness-time-coherence (STC) the STC projection.
in wave shape across the receiver array. In this
plot, from which local maxima of the coherence case, the wave shape stretches out in time from
contours can be identified (above). Maxima near receiver (bottom) to far receiver (top). The
change in wave shape is caused by dispersion.
38 Oilfield Review
6. changes across the receiver array, standard Up to now, this article has concentrated on
methods for estimating slowness, such as STC the simplest case of a homogeneous isotropic TIV
processing, which relies on wave-shape formation and monopole and dipole sources.
similarity, must be adapted to handle dispersive Such a formation has one P-wave slowness, one y Vertical axis x
of symmetry
waves. Dispersive STC processing identifies the Stoneley-wave slowness and one S-wave
slowness of individual frequency components.11 slowness. Most of the applications for using
A plot of flexural-wave slowness versus sonic-logging results to infer formation porosity,
frequency is called a dispersion curve (below). permeability, fluid type, elastic moduli, lithology z
Dispersion-curve analysis compares modeled or mineralogy have been developed for
acoustic dispersion curves for homogeneous homogeneous isotropic formations. Additional
isotropic formations with curves measured by complexities arise in inhomogeneous or
borehole sonic tools.12 anisotropic formations. The rest of this article
The radial depth of investigation of flexural addresses anisotropy first, then looks at
waves is approximately one wavelength. Low- inhomogeneous formations. TIH
frequency flexural waves probe deep into the
formation, and high-frequency flexural waves Anisotropy y
have shallower depths of investigation. Analysis The spatial alignment of mineral grains, layers, x
of flexural-mode slowness as a function of fractures or stress causes wave velocity to vary
Horizontal axis
frequency can therefore provide detailed with direction, a property called anisotropy.14 In of symmetry
information about the formation near and far seismic surveys, the anisotropy of the overburden
from the borehole. shales is known to cause imaging difficulties that
z
At zero frequency, flexural-wave slowness is need to be corrected to place reservoir targets at
the true formation shear slowness. Plotting the correct location. Information about aniso-
flexural-wave slowness versus frequency and tropy is also needed whenever an understanding
identifying the zero-frequency limit of the curve of rock mechanics is required. Directional
> Simplified geometries in elastic anisotropy. In
allow estimation of formation shear slowness. In drilling, drilling in tectonically active areas,
horizontal layers (top), elastic properties may be
this way, analysis of flexural-wave dispersion designing oriented-perforating jobs, planning uniform horizontally, but vary vertically. Such a
allows estimation of shear slowness in fast or hydraulic-fracturing operations and developing medium may be approximated as transversely
slow formations.13 pressure-supported recovery plans all benefit isotropic with a vertical axis of symmetry (TIV),
from knowledge of elastic anisotropy. meaning that the formation may be rotated about
the axis to produce a medium with the same
The natural processes that cause anisotropy properties. In formations with vertical fractures
also cause it to have one of two main (bottom), elastic properties may be uniform in
orientations: horizontal or vertical. To a first vertical planes parallel to the fractures, but may
400 vary in the perpendicular direction. This medium
approximation, horizontal layers create an
may be approximated as transversely isotropic
anisotropic medium that may be considered with a horizontal axis of symmetry (TIH).
Stoneley
isotropic in all horizontal directions, but
300
anisotropic vertically. Such a medium is known
as transversely isotropic with a vertical axis of
Slowness, µs/ft
10. Kimball CV and Marzetta TL: “Semblance Processing of
symmetry (TIV) (above right). Similarly, vertical Borehole Acoustic Array Data,” Geophysics 49, no. 3
200 (March 1984): 274–281.
Dipole fractures create a simplified anisotropic medium
flexural 11. Kimball CV: “Shear Slowness Measurement by
that may be considered isotropic in any direction Dispersive Processing of the Borehole Flexural Mode,”
aligned with fracture planes, and anisotropic in Geophysics 63, no. 2 (March–April 1998): 337–344.
100 Shear 12. Murray D, Plona T and Valero H-P: “Case Study of
the direction orthogonal to fracture planes. This
Borehole Sonic Dispersion Curve Analysis,”
medium is known as transversely isotropic with a Transactions of the SPWLA 45th Annual Logging
horizontal axis of symmetry (TIH). Symposium, June 6–9, 2004, Noordwijk, The
0 Netherlands, paper BB.
0 2 4 6 8 Sonic waves are sensitive to these directional The key parameters required for dispersion-curve
Frequency, kHz differences in material properties. Waves travel modeling are formation slowness, formation density,
> Dispersion curves characterizing slowness borehole-fluid velocity, borehole-fluid density and
fastest when the direction of particle motion, borehole diameter.
at different frequencies in an isotropic called polarization, is parallel to the direction of 13. Sinha BK and Zeroug S: “Geophysical Prospecting Using
formation. Shear waves are not dispersive; all Sonics and Ultrasonics,” in Webster JG (ed): Wiley
greatest stiffness. Compressional waves have
their frequency components travel at the same Encyclopedia of Electrical and Electronic Engineers
slowness. Stoneley waves are only slightly particle motion in the direction of propagation, Vol. 8. New York City: John Wiley and Sons, Inc. (1999):
dispersive. Flexural modes excited by a dipole so P-waves travel fastest in directions parallel to 340–365.
source exhibit large dispersion in this formation. 14. This holds for alignments on scales that are smaller than
layering and fractures, and travel more slowly the wavelength of the waves in question.
At the zero-frequency limit, flexural-wave
slowness tends to the shear-wave slowness
when perpendicular to layering and fractures. Armstrong P, Ireson D, Chmela B, Dodds K, Esmersoy C,
Miller D, Hornby B, Sayers C, Schoenberg M, Leaney S
(dotted line). and Lynn H: “The Promise of Elastic Anisotropy,”
Oilfield Review 6, no. 4 (October 1994): 36–47.
Spring 2006 39
7. n Compressional-
ctio
n dire wave amplitude
atio
pag
pro
ve
Wa e
Tim
A
Particle
motion
Slow shear-wave
amplitude
Particle e
motion Tim
B
Fast shear-wave
amplitude
Particle
motion e
Tim
C
Horizontal axis
of symmetry
> Particle motion and direction of propagation in compressional and shear waves.
Compressional waves (A) have particle motion in the direction of wave propagation. Shear
waves have particle motion orthogonal to the direction of propagation. In a TIH anisotropic
material (bottom), a shear wave propagating parallel to fractures splits. The S-wave with
vertically polarized particle motion, parallel to the fractures (C) is faster than the S-wave
with particle motion polarized orthogonal to fractures (B).
Shear waves have particle motion perpen- fractures is faster than the S-wave polarized Sonic logging can be used to detect and
dicular to the direction of propagation (above). orthogonal to layering or fractures. Flexural quantify the direction and magnitude of
In isotropic media, S-wave particle motion waves behave like S-waves, and so they split in anisotropy if the tool geometry and the
is contained in the plane containing the P the same ways. In the discussion that follows, S- anisotropy axis are properly aligned. In a TIH
and S raypaths. In anisotropic media, an waves and flexural waves are used medium, such as a formation with aligned
S-wave will split into two shear waves with interchangeably. vertical fractures, S-waves propagating along a
different polarizations and different velocities. vertical borehole split into two waves, and the
The S-wave polarized parallel to the layering or fast wave is polarized in the plane of the
40 Oilfield Review
8. Fast Receiver-13 ring
S-wave R13x R13y
Dipole
receivers R12y Receiver-12 ring
R12x
Slow R11y Receiver-11 ring
S-wave R11x
R10y Receiver-10 ring
R10x
R9y Receiver-9 ring
R9x
R8y Receiver-8 ring
R8x
R7y Receiver-7 ring Receiver array
R7x
R6y Receiver-6 ring
R6x
R5x R5y Receiver-5 ring
Source
Dipole pulse R4x Receiver-4 ring
source R4y
R3x Receiver-3 ring
R3y
R2x Receiver-2 ring
R2y
R1x Receiver-1 ring
R1y
> Shear-wave splitting in a vertical borehole in
a TIH medium with vertical fractures. No matter
how the dipole source is oriented relative to the Low-frequency
Undisturbed borehole
fast and slow directions of the medium, the shear flexural wave
wave will split into fast and slow components. borehole
(exaggerated)
The fast component aligns parallel to the plane
of the fractures, while the slow component aligns Dipole
transmitter
perpendicular to the plane of the fractures. pair
Ty
Tx
fractures (above). Similarly, in a TIV medium, Formation fast
such as a shale or a finely layered interval, S- shear-wave axis
θ y’
waves propagating in a horizontal borehole split, x y
and the fast wave becomes polarized in the Tool orientation
x’ Tool axis relative to formation
bedding plane.
> Inline and offline response on azimuthally distributed receivers from a
The polarization of S-waves split by
borehole flexural wave in an anisotropic formation. The flexural wave
anisotropy cannot be detected by a single was excited by firing of the X-dipole transmitter, Tx, shown at the bottom.
monopole receiver. Directional receivers are In this TIH medium, the flexural wave splits into fast and slow waves with
required. A suitable directional receiver can be components of particle motion on all receivers, not just those aligned
created by substituting a single monopole with the tool X-axis.
receiver with two or more pairs of monopole
receivers. Each pair of monopole receivers acts
as a dipole reciever. For adequate recording of
flexural waves, at least one dipole receiver is In isotropic formations, flexural waves formation’s fast and slow directions, flexural-
aligned with each dipole transmitter. At each generated by a dipole source remain polarized in wave energy will be recorded by the offline as
firing of the dipole source, signals are recorded the plane of the source and are detected only on well as the inline receivers.
by the dipole receiver oriented “inline” with that the dipole receiver aligned in that plane. The directions, or azimuths, of fast and slow
source and also by the dipole receiver oriented However, in anisotropic formations, the flexural shear or flexural waves can be seen in a crossed-
“offline” (above right).15 This example shows wave splits into fast and slow components dipole log. Creating a crossed-dipole log is a
recording of flexural waves at 13 receiver aligned with the formation anisotropy. Unless the multistep process. The first step is decompo-
stations with eight receivers distributed in a ring tool axes are fortuitously aligned with the sition and recombination of the waveforms
at each station.16
15. Offline is sometimes referred to as crossline. Radial, and Axial) Formation Acoustic Properties,”
16. Pistre V, Kinoshita T, Endo T, Schilling K, Pabon J, Transactions of the SPWLA 46th Annual Logging
Sinha B, Plona T, Ikegami T and Johnson D: “A Modular Symposium, New Orleans, June 26–29, 2005, paper P.
Wireline Sonic Tool for Measurements of 3D (Azimuthal,
Spring 2006 41
9. acquired on all sensors at each receiver station be fully characterized. For more complex types of boreholes identified inhomogeneities in the form
to yield four waveforms corresponding to the anisotropy, more measurements are required, of boundaries between horizontal layers (see
inline and offline responses at every depth to the such as P-waves propagating in different “History of Wireline Sonic Logging,” page 32).
two orthogonal dipole transmitters. Next, these azimuths or inclinations, or S-waves traveling Other heterogeneities, such as high-permeability
waveforms are mathematically rotated to put vertically and horizontally. Surface seismic and zones or open fractures that intersect the
them in a coordinate system consistent with the borehole seismic surveys often can provide this borehole, can be detected using Stoneley waves,
directions of maximum and minimum offline information. as described earlier.
waveform energy.17 Then, the waveforms corre- Formation properties that vary away from the
sponding to fast- and slow-shear orientations Inhomogeneity borehole, or along the radial axis, are evidence of
undergo semblance processing to obtain the fast Formation properties may vary not only with the drilling process and are more difficult to
and slow shear-wave slownesses.18 Zones with measurement direction, as in anisotropic forma- assess. The drilling process removes rock and
equal fast and slow shear-wave slownesses are tions, but also from place to place, in what are causes the in-situ stresses to redistribute, or
isotropic, while zones with large differences called inhomogeneous, or equivalently, hetero- concentrate, around the borehole in a well-known
between fast and slow shear-wave slownesses are geneous, formations. As with anisotropy, elastic manner.19 In addition, drilling not only
highly anisotropic. detecting and quantifying inhomogeneity using breaks the rock that is removed to form the
The slownesses of the fast and slow S-waves acoustic waves will depend on the type of borehole, but also may mechanically damage a
and the P- and Stoneley waves—the four slow- formation variation and its geometry relative to volume of rock surrounding the hole.20 This type of
nesses that can be measured by sonic logging in the borehole axis. damage is called plastic deformation, in contrast
an anisotropic medium—are transformed into Standard sonic logging can characterize to elastic, or reversible, deformation. In addition
four anisotropic moduli. These four moduli can formation properties that vary along the to plastic deformation, drilling fluid may react
almost characterize the simplest of anisotropic borehole. Early sonic-logging tools run in vertical with clays, causing swelling and altering near-
media. TIV and TIH media require five moduli to wellbore velocities. Mud that invades pore space
displaces formation fluids that probably have
different properties, also altering sonic velocities.
Drilling-induced variations may be more gradual
Fast Shear Slow Shear Compressional than variations across layer interfaces.
Differential Differential Differential
Measured depth, ft
17. Alford RM: “Shear Data in the Presence of Azimuthal
0 % 25 0 % 25 0 % 25 Anisotropy: Dilley, Texas,” Expanded Abstracts, 56th SEG
Gamma Annual International Meeting, Houston (November 2–6,
Distance from Distance from Distance from 1986): 476–479.
Borehole Center Ray Borehole Center Borehole Center
Brie A, Endo T, Hoyle D, Codazzi D, Esmersoy C, Hsu K,
2 ft 0 10 gAPI 110 0 ft 2 0 ft 2 Denoo S, Mueller MC, Plona T, Shenoy R and Sinha B:
“New Directions in Sonic Logging,” Oilfield Review 10,
no. 1 (Spring 1998): 40–55.
18. Esmersoy C, Koster K, Williams M, Boyd A and Kane M:
“Dipole Shear Anisotropy Logging,” Expanded Abstracts,
64th SEG Annual International Meeting, Los Angeles
X,480 (October 23–28, 1994): 1139–1142.
Kimball and Marzetta, reference 10.
19. Winkler KW, Sinha BK and Plona TJ: “Effects of
Borehole Stress Concentrations on Dipole Anisotropy
Measurements,” Geophysics 63, no. 1
(January–February 1998): 11–17.
20. Winkler KW: “Acoustic Evidence of Mechanical Damage
X,490 Surrounding Stressed Borehole,” Geophysics 62, no. 1
(January–February 1997): 16-22.
21. Zeroug S, Valero H-P and Bose S: “Monopole Radial
Profiling of Compressional Slowness,” prepared for
presentation at the 76th SEG Annual International
Meeting, New Orleans, October 1–3, 2006.
22. Sinha B, Vissapragada B, Kisra S, Sunaga S,
> Compressional and shear radial profiles in an anisotropic inhomogeneous Yamamoto H, Endo T, Valero HP, Renlie L and Bang J:
formation. The profile of variation in compressional slowness (Track 4) is created by “Optimal Well Completions Using Radial Profiling of
Formation Shear Slownesses,” paper SPE 95837,
tomographic reconstruction based on tracing rays through a modeled formation presented at the SPE Annual Technical Conference and
with properties that vary gradually away from the borehole. The percentage Exhibition, Dallas, October 9–12, 2005.
difference between observed slowness and slowness of the unaltered formation is Sinha BK: “Near-Wellbore Characterization Using Radial
plotted on color and distance scales to indicate the extent of difference away from Profiles of Shear Slownesses,” Expanded Abstracts,
the borehole. In these sandstones, identifiable from the gamma ray log in Track 2, 74th SEG Annual International Meeting, Denver
compressional slowness near the borehole varies by up to 15% from far-field (October 10–15, 2004): 326–329.
slowness, and the variation extends to more than 12 in. [30 cm] from the borehole 23. Chang C, Hoyle D, Watanabe S, Coates R, Kane R,
center. The borehole is shown as a gray zone. Shear radial profiles show the Dodds K, Esmersoy C and Foreman J: “Localized Maps
of the Subsurface,” Oilfield Review 10, no. 1 (Spring
difference between fast shear-wave slowness and far-field slowness (Track 1) and 1998): 56–66.
the difference between slow shear-wave slowness and far-field slowness (Track 3). 24. Hornby BE: “Imaging of Near-Borehole Structure Using
Large differences in shear slowness extend out to almost 10 in. [25 cm] from the Full-Waveform Sonic Data,” Geophysics 54, no. 6
borehole center. The radial variation in compressional and shear velocities is (June 1989): 747–757.
drilling-induced.
42 Oilfield Review
10. The sonic-imaging technique, sometimes
called the borehole acoustic reflection survey,
provides a high-resolution directional image of
Coal bed
reflectors up to tens of feet from the borehole
(left).23 Consequently, this technique has
significant potential application in horizontal
wells. To create an image, the tool records
waveforms of relatively long duration from the
Reflected monopole transmitters. Receivers must be
signals
distributed around the tool to allow the azimuths
of the reflections to be distinguished.
Complex data processing similar to that
designed for surface seismic surveys is applied in
Borehole signals
a multistep process. First, a compressional-
velocity model of the region in the vicinity of the
borehole is created using the P head waves.
Then, to extract reflected energy, the traditional
sonic arrivals, including P and S head waves and
> Sonic-imaging data-acquisition geometry. Designed to detect layer Stoneley waves, must be filtered from the
boundaries and other inhomogeneities roughly parallel to the borehole, the waveforms for each shot. The filtered traces are
sonic-imaging technique records reflected signals (red rays) from interfaces
tens of feet away. Borehole signals (black rays) must be filtered out. input to depth migration, a process that positions
reflections in their correct spatial location using
the velocity model.
The migration process formally converts a set
of amplitude and traveltime measurements into
a spatial image of the formation. This can be
Alteration in near-wellbore properties can receiver spacings. Ray-tracing techniques invert viewed as a triangulation process in which the
cause velocities to increase or decrease relative the refracted compressional arrivals to yield distance and the dip of a reflector relative to the
to the unaltered, or far-field, formation. Usually, compressional slowness versus distance from the borehole are determined by the signals recorded
drilling-induced damage reduces formation borehole.21 The difference between near- at receivers at different TR spacing. The
stiffness, causing velocities to decrease near the wellbore compressional slowness and far-field receivers at different azimuths around the
borehole. However, when drilling fluid replaces compressional slowness can be plotted along borehole measure different distances to a
gas as the pore-filling fluid, the resulting with depth of radial alteration (previous page). reflector depending on the azimuth and the dip
formation is stiffer, so compressional velocity In this example, radial variations of shear of the reflector relative to the borehole.
increases near the borehole. slownesses are also plotted. The sonic-imaging technique was developed
Radial alteration of rocks and fluids affects Radial variations in shear slowness are in the 1980s, but results have improved with
compressional and shear velocities differently. quantified through inversions of the broadband advances in sonic tools and processing
Alteration that reduces stiffness of the rock dispersions of flexural and Stoneley modes.22 At methods.24 The technique has been used to image
fabric, such as drilling-induced cracking or high frequencies, these dispersive modes steeply dipping beds from near-vertical
weakening, causes both P and S velocities to investigate the near-wellbore region, and at low boreholes and sedimentary boundaries from
decrease. However, a change in pore fluid has frequencies, they probe the unaltered formation horizontal wells. For examples of sonic imaging
little effect on S velocity, while P velocity may far from the borehole. Dispersion data from a and other applications of sonic measurements
change dramatically. For example, when drilling wide range of frequencies help produce the see “Sonic Investigations In and Around the
fluid replaces gas, P-wave velocity increases, but most reliable radial profiles of variations in Borehole,” page 14. –LS
S-wave velocity is relatively unaffected. shear slowness.
Complete characterization of radial inhomo- Some of the most challenging inhomo-
geneity requires analysis of radial variation of geneities to characterize are those that do not
compressional and shear slownesses. intersect the borehole. These may be vertical
A radial compressional-slowness profile is fractures or faults near a vertical borehole or
generated by collecting P-wave data for multiple sedimentary interfaces near a horizontal well.
depths of investigation, from near the wellbore to Detecting such inhomogeneities requires a
the unaltered, far-field formation. This requires method that looks deep into the formation and
recordings from a wide range of transmitter- that is able to detect abrupt changes in
formation properties.
Spring 2006 43