Mechanical wave

Mechanical waveMain

Community hub

Mechanical wave

8 pages, 0 posts

0 subscribers

Recent from talks

Be the first to start a discussion here.

Recent from talks

Be the first to start a discussion here.

Contribute something

About hubMembersContent overviewUpdatesRules

Main reference articles

Mechanical wave

View on Wikipedia

from Wikipedia

This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed.
Find sources: "Mechanical wave" – news · newspapers · books · scholar · JSTOR (April 2013) (Learn how and when to remove this message)

In physics, a mechanical wave is a wave that is an oscillation of matter, and therefore transfers energy through a material medium.^[1] Vacuum is, from classical perspective, a non-material medium, where electromagnetic waves propagate.

While waves can move over long distances, the movement of the medium of transmission—the material—is limited. Therefore, the oscillating material does not move far from its initial equilibrium position. Mechanical waves can be produced only in media which possess elasticity and inertia. There are three types of mechanical waves: transverse waves, longitudinal waves, and surface waves. Some of the most common examples of mechanical waves are water waves, sound waves, and seismic waves.

Like all waves, mechanical waves transport energy. This energy propagates in the same direction as the wave. A wave requires an initial energy input. Once this initial energy is added, the wave travels through the medium until all its energy is transferred. In contrast, electromagnetic waves require no medium, but can still travel through one.

Transverse wave

[edit]

A transverse wave is the form of a wave in which particles of medium vibrate about their mean position perpendicular to the direction of the motion of the wave.

Longitudinal wave

[edit]

Longitudinal waves cause the medium to vibrate parallel to the direction of the wave. It consists of multiple compressions and rarefactions. The rarefaction is the furthest distance apart in the longitudinal wave and the compression is the closest distance together. The speed of the longitudinal wave is increased in higher index of refraction, due to the closer proximity of the atoms in the medium that is being compressed. Sound is an example of a longitudinal wave.

Surface waves

[edit]

This type of wave travels along the surface or interface between two media. An example of a surface wave would be waves in a pool, or in an ocean, lake, or any other type of water body. There are two types of surface waves, namely Rayleigh waves and Love waves.

Rayleigh waves, also known as ground roll, are waves that travel as ripples with motion similar to waves on the surface of water. Such waves are much slower than body waves, at roughly 90% of the velocity of bulk waves^[clarify] for a typical homogeneous elastic medium. Rayleigh waves have energy losses only in two dimensions and are hence more destructive in earthquakes than conventional bulk waves, such as P-waves and S-waves, which lose energy in all three directions.

A Love wave is a surface wave having horizontal waves that are shear or transverse to the direction of propagation. They usually travel slightly faster than Rayleigh waves, at about 90% of the body wave velocity, and have the largest amplitude.

Examples

[edit]

Seismic waves
Sound waves
Wind waves on seas and lakes
Vibration

References

[edit]

^ Giancoli, D. C. (2009) Physics for scientists & engineers with modern physics (4th ed.). Upper Saddle River, N.J.: Pearson Prentice Hall.

Revisions and contributors Edit on Wikipedia Read on Wikipedia

View on Grokipedia

from Grokipedia

A mechanical wave is an organized disturbance or oscillation that propagates through a material medium, such as air, water, or a solid, by transferring energy from one particle to the next without causing a net displacement of the medium itself.^[1]^[2] These waves arise from the elastic properties of the medium, where particles oscillate around their equilibrium positions—either perpendicularly (transverse) or parallel (longitudinal) to the direction of wave travel—while the disturbance moves forward at a speed determined by the medium's tension, density, and elasticity.^[1]^[3] Mechanical waves are classified into three primary types based on the direction of particle motion relative to wave propagation. Transverse waves feature particle displacement perpendicular to the wave's direction, as seen in waves on a taut string or seismic S-waves in the Earth.^[1]^[3] Longitudinal waves involve particle motion parallel to the propagation direction, exemplified by sound waves in air or compressional seismic P-waves.^[1]^[2] Surface waves, a hybrid form, occur at the boundary between two media and combine transverse and longitudinal motions, such as ocean waves driven by wind or tsunamis generated by underwater earthquakes.^[3] Unlike electromagnetic waves, which propagate through vacuum via oscillating electric and magnetic fields, mechanical waves require a physical medium for transmission and cannot exist in empty space.^[3]^[1] Key properties of mechanical waves include wavelength (distance between consecutive crests or compressions), frequency (number of oscillations per second), amplitude (maximum displacement from equilibrium), and speed, which is the product of frequency and wavelength and varies with the medium—for instance, sound travels faster in water than in air due to the liquid's higher density and elasticity.^[2]^[1] These characteristics enable mechanical waves to carry information and energy over distances, underpinning phenomena from acoustic communication to seismic monitoring.^[3]^[2]

Fundamentals

Definition and Medium

A mechanical wave is a propagating disturbance in a physical medium that involves coordinated oscillations of the medium's particles, transferring energy and momentum from one location to another without resulting in any net displacement of the medium as a whole.^[4] In this process, individual particles vibrate about their equilibrium positions, interacting locally with neighboring particles to sustain the wave's forward motion.^[5] Propagation of mechanical waves requires an elastic medium—such as a solid, liquid, or gas—that can store and release elastic potential energy to restore displaced particles to their original positions.^[5] The medium's elastic properties provide the necessary restoring forces, while its inertial properties determine how particles respond to these forces during the disturbance.^[5] Without such elasticity, the disturbance could not propagate coherently through successive particle interactions.^[5] In contrast to electromagnetic waves, which propagate through oscillating electric and magnetic fields and require no material medium, mechanical waves cannot travel through a vacuum and depend entirely on the medium's particulate structure for energy transfer.^[4] The foundational idea linking wave propagation to particle motion within a medium traces back to Christiaan Huygens, who in 1678 developed a wave theory describing light as mechanical pressure waves transmitted through the elastic luminiferous ether.^[6]

Basic Characteristics

Mechanical waves are characterized by several fundamental parameters that describe their spatial and temporal behavior. The wavelength (

\lambda

), defined as the distance between two consecutive crests or troughs in the wave, quantifies the spatial extent of one complete oscillation./Book%3A_University_Physics_I_-Mechanics_Sound_Oscillations_and_Waves(OpenStax)/16%3A_Waves/16.02%3A_Characteristics_of_a_Sinusoidal_Wave) The frequency (

f

), measured in hertz (Hz), represents the number of oscillations or cycles that occur per second. Closely related is the period (

T

), which is the time required for one complete cycle and is inversely related to frequency by the equation

T = \frac{1}{f}

./Book%3A_University_Physics_I_-Mechanics_Sound_Oscillations_and_Waves(OpenStax)/16%3A_Waves/16.02%3A_Characteristics_of_a_Sinusoidal_Wave) The amplitude, the maximum displacement of the medium's particles from their equilibrium position, indicates the wave's intensity or energy level. Another key attribute is the phase, which describes the position of a point within the wave cycle relative to a reference point, often expressed in radians or degrees./Book%3A_University_Physics_I_-Mechanics_Sound_Oscillations_and_Waves(OpenStax)/16%3A_Waves/16.02%3A_Characteristics_of_a_Sinusoidal_Wave) The phase velocity refers to the speed at which a particular phase of the wave propagates through the medium, providing a measure of how quickly the wave pattern advances. In mechanical waves, energy propagates in the direction of the wave's travel, while the oscillation of particles in the medium occurs perpendicular to this direction in some cases, such as transverse waves, or parallel in others, like longitudinal waves./16%3A_Waves/16.01%3A_Traveling_Waves) Mechanical waves also exhibit damping and attenuation, where the wave's amplitude decreases over distance due to frictional losses and energy dissipation within the medium. This phenomenon arises from interactions like viscosity or internal friction, leading to a gradual reduction in wave energy as it travels./Book%3A_University_Physics_I_-Mechanics_Sound_Oscillations_and_Waves(OpenStax)/16%3A_Waves/16.07%3A_Damped_Harmonic_Motion)

Types

Transverse Waves

In transverse mechanical waves, the particles of the medium oscillate in a direction perpendicular to the direction of wave propagation, resulting in alternating crests (regions of maximum positive displacement) and troughs (regions of maximum negative displacement).^[7] This perpendicular motion distinguishes transverse waves from other types, enabling phenomena such as polarization that are not possible in waves where oscillations align with propagation.^[8] Transverse mechanical waves commonly propagate through solids, where shear forces can sustain the perpendicular displacements, as well as on stretched strings or surfaces under tension, such as a guitar string or a drumhead.^[9] In these media, the wave's behavior depends on the material's elastic properties and the applied forces. Polarization is a key characteristic of transverse waves, referring to the consistent orientation of the particle oscillations relative to the propagation direction; waves may be linearly polarized (oscillations confined to a single plane), circularly polarized (oscillations tracing a circle in a plane perpendicular to propagation), or elliptically polarized (a more general elliptical path).^[10] For instance, shaking a rope up and down produces a linearly polarized transverse wave in the vertical plane.^[8] Mathematically, a sinusoidal transverse wave propagating along the positive x-direction can be described by the displacement function

y(x,t) = A \sin(kx - \omega t + \phi),

where

A

is the amplitude,

k = 2\pi / \lambda

is the wave number (

\lambda

being the wavelength),

\omega = 2\pi f

is the angular frequency (

f

the frequency), and

\phi

is the phase constant.^[11] This form captures the periodic nature of the wave's transverse motion. For a specific case like waves on a stretched string, the propagation speed

v

is determined by

v = \sqrt{T / \mu}

v=T/μ

, where $T$ is the tension force and $\mu$ is the linear mass density (mass per unit length) of the string; higher tension increases speed, while greater density decreases it.^[12] Unlike longitudinal waves, in which particle motion parallels the propagation direction, transverse waves require a medium capable of resisting shear.^[13]

Longitudinal Waves

Longitudinal mechanical waves are characterized by particle oscillations that occur parallel to the direction of wave propagation, distinguishing them from other wave types. In such waves, the medium experiences alternating regions of compression, where particles are displaced closer together and pressure increases, and rarefactions, where particles spread apart and pressure decreases, all aligned along the propagation axis. This pattern arises as the disturbance travels through the medium, with each particle vibrating back and forth without net displacement from its equilibrium position.^[14]^[9]^[15] Due to the linear and symmetric nature of particle motion confined to the propagation direction, longitudinal waves exhibit no polarization, as there is no transverse component that could be restricted to a particular plane or direction.^[16]^[17] This isotropy in the transverse plane prevents selective filtering based on orientation, a property that contrasts with waves involving perpendicular oscillations. Longitudinal waves propagate effectively in gases, liquids, and solids, where the medium's compressibility—quantified by the bulk modulus—allows for the necessary volume changes during compression and rarefaction.^[18]^[19] Unlike transverse waves, which require shear strength typically found in solids, longitudinal waves can travel through fluids lacking such rigidity.^[20] The propagation speed of longitudinal waves in fluids is determined by the formula

v = \sqrt{\frac{B}{\rho}},

v=ρB

, where $B$ is the adiabatic bulk modulus (measuring resistance to uniform compression) and $\rho$ is the medium's density.^[21]^[22] In gases, assuming ideal behavior and adiabatic processes, this expression simplifies to $v = \sqrt{\frac{\gamma P}{\rho}},$

, with $\gamma$ as the adiabatic index (ratio of specific heats) and $P$ as the equilibrium pressure; this form highlights how speed increases with temperature, as higher temperatures raise pressure or lower density for a fixed volume.^[23]^[24] These speeds underscore the wave's dependence on the medium's elastic and inertial properties, enabling efficient energy transfer in compressible materials. At interfaces between media, longitudinal waves interact via acoustic impedance, defined as $Z = \rho v$ , which quantifies the medium's opposition to wave motion by relating pressure to particle velocity.^[25]^[26] When a wave strikes a boundary, the impedance mismatch governs reflection and transmission: the amplitude reflection coefficient for pressure is $R = \frac{Z_2 - Z_1}{Z_2 + Z_1},$ where $Z_1$ and $Z_2$ are the impedances of the incident and second medium, respectively. A large mismatch, such as air meeting a solid surface (high $Z_2$ ), results in near-total reflection with a phase inversion for displacement, producing effects like echoes; conversely, similar impedances allow greater transmission.^[27]^[28] This behavior is crucial for applications in acoustics and seismology, where boundary reflections reveal medium properties.^[29]

Surface Waves

Surface waves are mechanical waves that propagate along the boundary or interface between two media, such as the surface of a solid or liquid, where the motion of particles is confined primarily to a thin layer near the boundary. Unlike purely transverse or longitudinal waves that occur in the bulk of a medium, surface waves exhibit a hybrid motion where particles trace elliptical or circular paths, combining vertical and horizontal displacements perpendicular to the direction of propagation. This elliptical particle motion arises from the interaction of shear and compressional components at the interface, resulting in a rolling or retrograde orbital pattern that diminishes rapidly with depth below the surface.^[4]^[30]^[31] Several distinct types of surface waves exist, depending on the media and the dominant restoring forces. In solids, Rayleigh waves produce a rolling motion similar to ocean waves, with particles moving in elliptical orbits that are retrograde near the surface and prograde below it, propagating along free surfaces or interfaces between solids. Love waves, observed primarily in earthquakes, involve horizontal shear motion parallel to the surface and perpendicular to the propagation direction, behaving as transversely polarized waves confined to layered media like the Earth's crust. In liquids, gravity waves dominate for longer wavelengths where buoyancy provides the restoring force, while capillary waves prevail for shorter wavelengths under the influence of surface tension, both occurring at the air-water interface.^[30]^[31]^[32] Surface waves are inherently dispersive, meaning their propagation speed depends on wavelength, which affects how wave packets spread over distance. For deep-water gravity waves, the phase speed

v

approximates

\sqrt{\frac{g \lambda}{2\pi}}

2πgλ

, where $g$ is gravitational acceleration and $\lambda$ is wavelength, indicating that longer waves travel faster than shorter ones in water depths much greater than the wavelength. This dispersion relation stems from the balance between gravitational restoring forces and inertial effects in the linearized wave equation for inviscid fluids. Similarly, capillary waves show even stronger dispersion due to surface tension, with speed increasing for shorter wavelengths.^[33]^[32] The confinement of surface waves to boundaries leads to energy concentration near the interface, often resulting in higher amplitudes compared to body waves propagating through the interior of the medium. This localization enhances the waves' ability to transport energy efficiently along the surface while decaying exponentially away from it, with amplitudes typically larger due to reduced dissipation in the thin boundary layer. In seismic contexts, this energy focusing contributes to the greater destructive potential of surface waves during earthquakes.^[30] In geophysics, surface waves play a crucial role in earthquake detection and subsurface imaging, as their lower frequencies and surface-trapped propagation allow for long-distance travel and sensitive recording by seismometers. Techniques like surface wave tomography use Rayleigh and Love waves to map shear-wave velocity variations in the Earth's crust and upper mantle, aiding in the location of epicenters and assessment of fault zones. Active-source methods, such as multichannel analysis of surface waves (MASW), employ generated Rayleigh waves to profile near-surface stiffness for geotechnical applications, including void and fracture detection.^[34]^[35]^[36]

Properties

Wave Speed and Factors

The speed of a mechanical wave, denoted as

v

, is fundamentally related to its frequency

f

and wavelength

\lambda

through the equation

v = f \lambda

This relationship holds for all mechanical waves propagating through a medium, where frequency remains constant while wavelength adjusts to accommodate variations in speed.^[37] The propagation speed of mechanical waves is primarily determined by the elastic properties of the medium, which provide the restoring force for wave motion, and its inertial properties, particularly density. In solids, the relevant elastic property is Young's modulus

Y

, a measure of stiffness under tension or compression, leading to speeds on the order of thousands of meters per second. In fluids, the bulk modulus

\beta

, which quantifies resistance to uniform compression, governs the speed, typically resulting in values around 1500 m/s in water. Density

\rho

acts inversely, as wave speed scales with

\sqrt{1/\rho}

1/ρ

for a fixed elastic modulus; however, since elastic properties increase significantly from gases to liquids to solids, waves typically propagate more quickly in denser media like liquids and solids compared to gases (e.g., sound speed: air ~343 m/s, water ~1480 m/s, steel ~5960 m/s).^[38]^[39]^[40] Temperature influences wave speed, particularly in gases, where it affects molecular kinetic energy and thus the medium's elasticity. For ideal gases, speed increases proportionally with the square root of the absolute temperature $T$ , as higher temperatures enhance collision rates without significantly altering density under constant pressure. In solids and liquids, the effect is smaller, often less than 1% per degree Celsius.^[37] In crystalline solids, wave speeds exhibit anisotropy, varying with the direction of propagation due to the medium's directional elastic properties; for instance, longitudinal waves may travel faster along certain crystallographic axes than others.^[41] When the source or observer moves relative to the medium, the observed frequency shifts via the Doppler effect, given by $f' = f \frac{v \pm v_o}{v \mp v_s}$ where $v$ is the wave speed in the medium, $v_o$ is the observer's speed (positive toward the source), and $v_s$ is the source's speed (positive away from the observer); the signs account for approach or recession. This effect alters perceived pitch for sound waves but does not change the intrinsic speed.^[42] In laboratory settings, wave speed is commonly measured using the time-of-flight method, where a pulse is generated and the time for it to travel a known distance to a detector is recorded, yielding $v = d / t$ . This technique applies to various media, such as air columns or solid rods, and provides precise values when combined with high-resolution timing.^[43]

Energy and Amplitude

Mechanical waves transport energy through the oscillations of particles in a medium, with the amount of energy carried directly related to the wave's amplitude. The average energy density

u

of a harmonic mechanical wave is proportional to the square of the amplitude

A

, specifically

u \propto \rho \omega^2 A^2

, where

\rho

is the density of the medium and

\omega

is the angular frequency. This relationship arises because both kinetic and potential energies in the oscillating particles scale with

A^2

, similar to simple harmonic motion. For example, in a transverse wave on a string, the average energy per unit length is

\frac{1}{2} \mu \omega^2 A^2

, where

\mu

is the linear mass density.^[44]^[45] The power transmitted by a mechanical wave, which quantifies the rate of energy transfer, also depends strongly on amplitude. For a plane harmonic wave, the intensity

I

, defined as the average power per unit area perpendicular to the propagation direction, is given by

I = \frac{1}{2} \rho v \omega^2 A^2

, where

v

is the wave speed. This formula applies to longitudinal waves like sound in fluids, highlighting how higher amplitudes and frequencies increase energy flux. In transverse waves on a string, the average power is

P = \frac{1}{2} \mu \omega^2 A^2 v

, demonstrating the same quadratic dependence on amplitude and frequency.^[46]^[45]^[44] In ideal, non-dissipative media, mechanical waves conserve energy, with the total energy remaining constant as the wave propagates, though the amplitude may decrease in spreading geometries like spherical waves due to energy distribution over larger areas. However, real media introduce dissipation through mechanisms such as viscosity and internal friction, which convert mechanical energy into thermal energy, reducing the wave's overall energy. Viscosity causes shearing forces between fluid layers, leading to frictional losses proportional to the square of the velocity gradient.^[44]^[47]^[48] This dissipation manifests as an exponential decay in amplitude with propagation distance in damped mechanical waves, described by

A(x) = A_0 e^{-\alpha x}

, where

A_0

is the initial amplitude and

\alpha

is the attenuation coefficient that depends on the medium's viscosity and the wave's frequency. Higher frequencies typically experience greater attenuation due to increased viscous drag on oscillating particles. In solids, additional frictional losses at grain boundaries or defects contribute to this decay.^[49]^[50] At sufficiently high amplitudes, the linear approximations break down, and nonlinear effects become prominent in mechanical waves, causing the waveform to distort as faster-moving parts of the wave overtake slower ones, eventually forming steep fronts known as shock waves. This steepening occurs in compressible media like air or water, where the wave speed varies with amplitude, leading to phenomena such as sonic booms or explosive shock fronts. In gases, the nonlinear wave equation reveals how initial smooth profiles evolve into discontinuous shocks, dissipating energy abruptly through irreversible processes.^[51]^[52]

Superposition and Interference

The principle of superposition states that when two or more mechanical waves overlap in a medium, the resultant displacement at any point is the vector sum of the individual displacements produced by each wave acting alone.^[5] This linear superposition holds for small-amplitude waves in elastic media where interactions between waves do not significantly alter the medium's properties.^[53] Interference arises from this superposition when waves combine coherently, leading to regions of enhanced or reduced amplitude. Constructive interference occurs when waves are in phase, meaning their crests or troughs align, resulting in a maximum amplitude up to twice that of the individual waves (2A for equal amplitudes).^[54] Destructive interference happens when waves are out of phase by π radians, causing crests to align with troughs and potentially reducing the amplitude to zero for equal waves.^[55] These patterns are observable in mechanical systems like overlapping pulses on a string or sound waves in air.^[56] Standing waves form when two waves of the same frequency travel in opposite directions and interfere, often due to reflection from boundaries, creating a stationary pattern with fixed points of zero displacement called nodes and points of maximum displacement called antinodes.^[57] In a string fixed at both ends, such as a guitar string, the fundamental mode has antinodes at the center and nodes at the ends, with the distance between consecutive nodes equal to half a wavelength. Higher harmonics feature additional nodes and antinodes, enabling resonant frequencies that sustain the wave without continuous energy input. Beats occur when two mechanical waves of slightly different frequencies superpose, producing an amplitude modulation with a beat frequency equal to the absolute difference between the individual frequencies,

f_{\text{beat}} = |f_1 - f_2|

.^[58] This phenomenon is prominent in sound waves, such as from two nearby tuning forks, where the intensity waxes and wanes periodically, allowing musicians to tune instruments by listening for minimal beats.^[59] The envelope of the resultant wave travels at the average group velocity, while the rapid oscillations occur at the average frequency.^[5] In mechanical waves, diffraction refers to the bending and spreading of waves around obstacles or through apertures comparable to the wavelength, governed by superposition of wavelets from Huygens' principle.^[60] For instance, sound waves diffract around doorways, allowing low-frequency bass notes to be heard more readily than high-frequency tones. Dispersion describes how wave speed varies with frequency or wavelength in non-uniform media, causing wave packets to spread over time as different components travel at different velocities.^[61] This effect is evident in water surface waves, where shorter waves slow down more than longer ones, leading to the characteristic dispersion of ocean swells.^[5]

Mathematical Description

Wave Equation

The one-dimensional wave equation describes the propagation of mechanical disturbances along a continuous medium, such as a vibrating string, and is given by

\frac{\partial^2 u}{\partial t^2} = v^2 \frac{\partial^2 u}{\partial x^2},

where

u(x, t)

represents the transverse displacement at position

x

and time

t

, and

v

is the wave speed determined by the medium's properties.^[62] This equation, first derived by Jean le Rond d'Alembert in 1747 for the vibrating string problem, models small-amplitude waves under the assumption of linearity.^[63] The derivation begins by considering a flexible string under constant tension

T

with linear mass density

\mu

, assuming small displacements so that the tension remains approximately constant and the motion is transverse. Applying Newton's second law to an infinitesimal segment of length

\Delta x

, the net force due to tension differences at the endpoints yields

\mu \Delta x \frac{\partial^2 u}{\partial t^2} = T \left( \frac{\partial u}{\partial x} \bigg|_{x+\Delta x} - \frac{\partial u}{\partial x} \bigg|_x \right)

μΔx∂t2∂2u=T(∂x∂u

x+Δx−∂x∂u

x). For small slopes, Hooke's law approximates the restoring force via the curvature, leading to the second spatial derivative after taking the limit $\Delta x \to 0$ , resulting in the wave equation with $v = \sqrt{T/\mu}$

.^[64]^[65] This form also applies to longitudinal waves in springs or rods, where Hooke's law directly relates stress to strain, and Newton's law balances inertial and elastic forces.^[66] In three dimensions, the wave equation generalizes to the scalar form $\frac{\partial^2 \psi}{\partial t^2} = v^2 \nabla^2 \psi,$ where $\nabla^2$ is the Laplacian operator, applicable to displacement potentials or scalar fields in isotropic media for approximations like acoustic waves.^[64] For vector displacements in elastic media, it becomes $\rho \frac{\partial^2 \mathbf{u}}{\partial t^2} = (\lambda + 2\mu) \nabla (\nabla \cdot \mathbf{u}) - \mu \nabla \times (\nabla \times \mathbf{u})$ , where $\rho$ is density, $\lambda$ and $\mu$ are Lamé parameters, recovering compressional and shear waves.^[67] In anisotropic media, such as crystals, the equation incorporates direction-dependent elastic properties via the stiffness tensor $C_{ijkl}$ , yielding $\rho \frac{\partial^2 u_i}{\partial t^2} = \frac{\partial}{\partial x_j} (C_{ijkl} \frac{\partial u_k}{\partial x_l})$ , which couples wave speeds to propagation direction.^[68] Boundary conditions specify the behavior at the domain edges and are essential for well-posed problems. Fixed (Dirichlet) conditions enforce $u = 0$ at boundaries, modeling clamped ends; free (Neumann) conditions set $\frac{\partial u}{\partial n} = 0$ , representing unattached surfaces with no transverse force; periodic conditions identify opposite boundaries, $u(0, t) = u(L, t)$ and $\frac{\partial u}{\partial x}(0, t) = \frac{\partial u}{\partial x}(L, t)$ , for waves on rings or periodic structures.^[69]^[70] For the one-dimensional infinite domain with initial conditions $u(x, 0) = f(x)$ and $\frac{\partial u}{\partial t}(x, 0) = g(x)$ , d'Alembert's formula provides the exact solution: $u(x, t) = \frac{f(x + v t) + f(x - v t)}{2} + \frac{1}{2v} \int_{x - v t}^{x + v t} g(s) \, ds.$ This expresses the wave as right- and left-propagating components, preserving the initial profile without distortion.^[71]^[66]

Harmonic Waves

Harmonic waves, also known as sinusoidal waves, represent a fundamental class of periodic mechanical waves where the displacement of particles in the medium follows a simple harmonic motion. These waves are characterized by a constant amplitude and frequency, making them ideal for analytical treatment in wave mechanics. The general mathematical form for a harmonic wave propagating in the positive x-direction is given by

u(x, t) = A \cos(kx - \omega t + \phi),

where

A

is the amplitude,

k

is the wave number defined as

k = \frac{2\pi}{\lambda}

with

\lambda

being the wavelength,

\omega

is the angular frequency, and

\phi

is the phase constant.^[5] An equivalent complex representation, often used for mathematical convenience in derivations, is

u(x, t) = A e^{i(kx - \omega t + \phi)}

, where the physical displacement is the real part of this expression.^[5] The dispersion relation for harmonic waves in non-dispersive media links the angular frequency to the wave number via

\omega = v k

, where

v

is the constant wave speed.^[5] This relation implies that all frequency components travel at the same speed, simplifying the propagation analysis. In dispersive media, however,

v

depends on frequency, leading to different behaviors for phase and group velocities. Fourier analysis provides a powerful tool for decomposing arbitrary mechanical waves into a superposition of harmonic waves. Any periodic or aperiodic waveform can be expressed as an integral over harmonic components, such as

f(t) = \int_{-\infty}^{\infty} d\omega \, C(\omega) e^{-i\omega t}

, where

C(\omega)

is the Fourier transform amplitude spectrum.^[72] This decomposition is essential for understanding complex wave packets and non-sinusoidal disturbances in mechanical systems. The phase velocity

v_p = \frac{\omega}{k}

describes the speed at which a point of constant phase, such as a wave crest, propagates through the medium.^[5] In contrast, the group velocity

v_g = \frac{d\omega}{dk}

represents the velocity of the overall wave envelope or energy transport, which is particularly relevant in dispersive media where different harmonics travel at varying speeds.^[72] For non-dispersive cases like waves on a taut string,

v_p = v_g = v

. In mechanical engineering, harmonic waves underpin signal processing techniques for analyzing vibrations in systems such as rotating machinery and structures, enabling fault detection and response prediction through spectral decomposition.^[73]

Applications and Examples

Sound Waves

Sound waves are a primary example of mechanical longitudinal waves, propagating as alternating compressions and rarefactions of pressure in a medium such as air, water, or solids. In air, these waves travel by vibrating air molecules in the direction of wave propagation, creating regions of high and low pressure that enable the transmission of audible information. The human ear perceives sound within a frequency range of approximately 20 Hz to 20 kHz, with sensitivity peaking around 2-5 kHz; frequencies below 20 Hz are infrasound, and those above 20 kHz are ultrasound, both inaudible to most humans. The speed of sound in dry air at sea level and 20°C is approximately 343 m/s, but it varies significantly with temperature due to the increased molecular kinetic energy that facilitates faster pressure wave propagation. A common empirical approximation for this dependence is

v \approx 331 + 0.6T

m/s, where

T

is the temperature in Celsius; for instance, at 0°C, the speed drops to about 331 m/s, while at 30°C, it rises to around 349 m/s. This temperature sensitivity is crucial for applications like atmospheric acoustics, where altitude and weather conditions further influence propagation. In other media, such as water (about 1480 m/s at 20°C) or steel (around 5000-6000 m/s), the speed is higher due to greater medium stiffness and density effects. Sound intensity, which quantifies the power per unit area carried by the wave, is logarithmically scaled in decibels to match human perception. The sound pressure level (SPL) is defined as

\text{SPL} = 20 \log_{10} \left( \frac{p}{p_0} \right)

dB, where

p

is the root-mean-square pressure amplitude and

p_0 = 20 \, \mu\text{Pa}

is the reference threshold of human hearing at 1 kHz. At this threshold, SPL is 0 dB; conversational speech typically reaches 60 dB, while painful levels exceed 120 dB. Absorption and reflection in enclosed spaces affect intensity distribution, leading to reverberation—the persistence of sound after the source stops due to multiple reflections off surfaces. Reverberation time, often calculated via Sabine's formula

T = 0.161 \frac{V}{A}

(where

V

is room volume and

A

is total absorption), ideally balances clarity and warmth in auditoriums, with materials like foam or curtains enhancing absorption to reduce echoes. Beyond the audible range, ultrasound waves (frequencies above 20 kHz) exploit the same longitudinal principles for non-audible applications, particularly in medicine. In medical imaging, high-frequency ultrasound pulses (typically 2-18 MHz) reflect off tissue interfaces to generate detailed 2D or 3D images via pulse-echo techniques, enabling real-time visualization of organs, blood flow (through Doppler shifts), and fetal development without ionizing radiation. This technology, pioneered in the mid-20th century, relies on the wave's ability to penetrate soft tissues while being attenuated by bone or air, with safety limits set by organizations like the FDA to avoid thermal or cavitation effects.

Seismic Waves

Seismic waves are mechanical waves generated by the sudden release of energy during earthquakes, propagating through Earth's interior and along its surface. These waves provide critical insights into the planet's structure and dynamics, as they travel at different speeds and polarizations depending on the medium. Earthquakes primarily produce two categories of seismic waves: body waves that traverse the interior and surface waves that follow the planet's outer layers. Body waves arrive first at distant locations, followed by slower surface waves that often cause the most extensive damage due to their prolonged ground motion.^[74] Body waves consist of primary (P) waves and secondary (S) waves. P-waves are longitudinal, compressing and expanding rock particles parallel to their direction of propagation, making them the fastest seismic waves with speeds of approximately 5 to 8 km/s in the Earth's crust.^[75] S-waves are transverse, causing particles to move perpendicular to the propagation direction, and travel at about half the speed of P-waves, roughly 3 to 4.5 km/s in the crust; these waves cannot pass through liquids, such as Earth's outer core.^[75] Like other transverse mechanical waves, S-waves shear the medium without net volume change.^[74] Surface waves include Rayleigh and Love waves, which travel more slowly than body waves along the Earth's surface, typically at 2 to 4 km/s, but generate stronger amplitudes that lead to greater destruction.^[75] Rayleigh waves produce elliptical particle motion in the vertical plane, combining longitudinal and vertical components to create a rolling effect on the ground.^[74] Love waves, in contrast, cause horizontal shearing perpendicular to propagation with no vertical motion, resulting in side-to-side shaking that amplifies damage to structures.^[74] These waves are particularly destructive because their energy is confined near the surface and persists longer than body waves.^[76] As seismic waves propagate through Earth's heterogeneous layers, they undergo attenuation, losing energy through both intrinsic absorption and scattering. Scattering occurs when waves interact with small-scale inhomogeneities in the crust and mantle, redirecting energy into coda waves—diffuse, prolonged signals that reveal the medium's heterogeneity.^[77] Attenuation is quantified by the quality factor Q, which increases with frequency and varies regionally; for instance, scattering coefficients around 0.02 km⁻¹ have been measured in crustal studies at 1.5 to 3 Hz.^[77] In the upper mantle and lithosphere, random velocity fluctuations on scales of kilometers contribute significantly to this scattering, diminishing high-frequency components more rapidly than low ones.^[77] Seismographs detect these waves by recording ground motion, enabling precise measurement of arrival times to determine earthquake locations. The time difference between P-wave and S-wave arrivals at a station corresponds to the epicentral distance, as P-waves outpace S-waves; this interval is used with travel-time curves to estimate distance, and data from at least three stations allow triangulation of the epicenter via intersecting great-circle arcs.^[78] Modern networks refine this by modeling wave paths through layered Earth structures, improving accuracy for depths and origins.^[78] The 1906 San Francisco earthquake, with a magnitude of about 7.9, exemplified the role of seismic wave analysis in advancing geophysics. Recorded by 96 global stations, its waves revealed fault rupture along nearly 480 km of the San Andreas Fault, with surface waves causing intense shaking that destroyed much of the city.^[79] Analysis of these records, detailed in the 1908 Lawson Report, supported H.F. Reid's elastic rebound theory, explaining how accumulated strain releases as seismic waves, marking a pivotal shift toward systematic earthquake science.^[80]

Water Waves

Water waves are mechanical waves that propagate along the interface between a liquid, typically water, and a gas, such as air, where the restoring forces arise primarily from gravity and surface tension. These waves are generated by disturbances like wind, gravitational interactions, or seismic events and are characterized by their oscillatory motion confined to the surface layer, with energy transported horizontally. Unlike bulk waves in solids or fluids, water waves exhibit dispersion, where phase velocity depends on wavelength, leading to phenomena like wave spreading and breaking.^[33] Gravity waves dominate for wavelengths longer than about 1.7 cm on water surfaces, where gravity provides the primary restoring force. In deep water, where the depth exceeds half the wavelength, the phase velocity

v

follows the dispersion relation

v = \sqrt{\frac{g \lambda}{2\pi}}

v=2πgλ

, with $g$ as gravitational acceleration and $\lambda$ as wavelength, indicating longer waves travel faster.^[33] In shallow water, where depth $h$ is much less than wavelength, the velocity simplifies to $v = \sqrt{gh}$

, making wave speed independent of wavelength and dependent only on local depth.^[81] This shallow-water approximation explains the rapid propagation of tsunamis, which are long-wavelength gravity waves generated by underwater earthquakes; in the open ocean with depths around 4 km, their speeds reach up to 800 km/h.^[82] For shorter wavelengths, typically below 1.7 cm, capillary waves prevail, with surface tension $\sigma$ acting as the dominant restoring force over gravity. The phase velocity scales as $v \propto \sqrt{\frac{\sigma}{\rho}} \lambda^{-1/2}$

λ−1/2, where $\rho$ is fluid density, resulting in shorter waves moving slower and exhibiting higher frequencies.^[83] These waves often appear as ripples on calm water surfaces and contribute to the fine-scale texture observed in wind-generated seas. Nonlinear effects become prominent in steep waves, leading to wave breaking, where the wave crest overturns due to imbalance between propagation speed and particle velocity at the surface. Rogue waves, unusually large and steep surface elevations exceeding twice the surrounding significant wave height, emerge from nonlinear superposition of wave trains, such as through modulation instability or breather solutions in the nonlinear Schrödinger equation.^[84] These phenomena pose hazards to maritime navigation and offshore structures. In coastal engineering, breakwaters are offshore structures designed to mitigate wave energy by reflecting, dissipating, or diffracting incoming waves, thereby reducing erosion and protecting harbors. Detached or submerged breakwaters can attenuate wave heights by up to 80% in their lee, fostering calmer waters for sediment accretion and infrastructure stability.^[85]

History

Media collections

Mechanical wave

Recent from talks

Recent from talks

Contribute something

Contribute something

Media Pages

Timelines

Articles

Notes collections

Notes

Notes

Days in Chronicle

Mechanical wave

Transverse wave

Longitudinal wave

Surface waves

Examples

See also

References

Mechanical wave

Fundamentals

Definition and Medium

Basic Characteristics

Types

Transverse Waves

Add your contribution

Related Hubs

Contribute something