Particle acceleration

This article is about small-scale particle acceleration in acoustics. For acceleration of charged particles to very high energies, see particle accelerator.

In a compressible sound transmission medium - mainly air - air particles get an accelerated motion: the particle acceleration or sound acceleration with the symbol a in metre/second². In acoustics or physics, acceleration (symbol: a) is defined as the rate of change (or time derivative) of velocity. It is thus a vector quantity with dimension length/time². In SI units, this is m/s².

To accelerate an object (air particle) is to change its velocity over a period. Acceleration is defined technically as "the rate of change of velocity of an object with respect to time" and is given by the equation

\mathbf{a} = {d\mathbf{v}\over dt}

where

a is the acceleration vector
v is the velocity vector expressed in m/s
t is time expressed in seconds.

This equation gives a the units of m/(s·s), or m/s² (read as "metres per second per second", or "metres per second squared").

An alternative equation is:

\mathbf{\bar{a}} = {\mathbf{v} - \mathbf{u} \over t}

where

\mathbf{\bar{a}}

is the average acceleration (m/s²)

$\mathbf{u}$ is the initial velocity (m/s)

$\mathbf{v}$ is the final velocity (m/s)

$t$ is the time interval (s)

Transverse acceleration (perpendicular to velocity) causes change in direction. If it is constant in magnitude and changing in direction with the velocity, we get a circular motion. For this centripetal acceleration we have

\mathbf{a} = - \frac{v^2}{r} \frac{\mathbf{r}}{r} = - \omega^2 \mathbf{r}

One common unit of acceleration is g-force, one g being the acceleration caused by the gravity of Earth.

In classical mechanics, acceleration $a \$ is related to force $F \$ and mass $m \$ (assumed to be constant) by way of Newton's second law:

F = m \cdot a

Equations in terms of other measurements

The Particle acceleration of the air particles a in m/s² of a plain sound wave is:

a = \delta \cdot \omega^2 = v \cdot \omega = \frac{p \cdot \omega}{Z} = \omega \sqrt \frac{J}{Z} = \omega \sqrt \frac{E}{\rho} = \omega \sqrt \frac{P_{ac}}{Z \cdot A}

Symbol	Units	Meaning
a	m/s²	particle acceleration
v	m/s	particle velocity
δ	m, meters	particle displacement
$\omega$ = 2 · $\pi$ · f	radians/s	angular frequency
f	Hz, hertz	frequency
p	Pa, pascals	sound pressure
Z	N·s/m³	acoustic impedance
J	W/m²	sound intensity
E	W·s/m³	sound energy density
P_ac	W, watts	sound power or acoustic power
A	m²	area

External links

Relationships of acoustic quantities associated with a plane progressive acoustic sound wave - pdf

This article is issued from Wikipedia - version of the Sunday, April 24, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.

Particle acceleration

Equations in terms of other measurements

See also

External links