in a medium through which it expand

in a medium through which it expands and the orientation
of its movement as the efficiency of the propagation of sound
in a particular direction. Therefore, the density of the
media has an important role in relation to both the speed
and the intensity, because in dense media sound spreads
faster and at the same time has lower power consumption,
and its intensity decreases more slowly. That is of importance
for understanding the audibility of sound because
the sound intensity when, for example, it is heard by whale
is different than when the sound is created, so the information
about its distance from the source is to be known.
Likewise, the expansion rate e.g. in the sea also depends
on its temperature, depth (pressure), salinity, season, geographical
location and time of day, and, generally speaking,
it can be said that it changes within limits of 1440 to 1550
m/s (Figures 1 and 2). At the same time, to calculate the
speed of sound in the sea, ‘different authors use different
formulas’, and for practical applications in most cases a
simplified Leroy’s formula can be applied [10]:
c = 1412 +3,21∙T +1,19 ∙ S + 0,0167∙Z [m/s] (3)
where:
c – the speed of sound in m/s
T – temperature in °C
S – salinity in ‰
Z – depth in meters.
From Figures 1 and 2 it is obvious that by increasing
the depth the temperature and speed of sound are proportionally
lowered, but it is of importance to note that the
greatest change is in the surface layer (up to a depth of approximately
700 m) where the expansion rate decreases
significantly with the depth, while in the deeper layers it is
of a moderate decline. The speed of sound, when depending
on the change of salinity, (in the area of 34–35 ‰) is
almost a proportional increase (increase in salinity of 1
PSU results in the increase of speed by 1.3 m/s), as can be
seen in the diagram on the pressure dependence, because
when the depth and pressure increase, the speed increases
proportionally (increase in pressure by 1 Pa results in
the increased speed of 1.7 m/s).
As can be seen in Figure 2, there is a maximum speed
of expansion in the upper layers representing the seasonal
thermocline, and a sudden drop and the minimum expansion
rate that is achieved at the lowest layers of the permanent
thermocline, while in layers representing the deep isothermal
area the expansion rate increases proportionally.
To understand the impact of sound in water, it is necessary
to distinguish between pulsating (single and multiple)
and non pulsating sounds, and their differences in the effects
on marine organisms. Single pulses are those that look
like explosions, single air gun, or a single ‘ping’ of some sonar,
while multiple pulses are those caused by e.g. multiple
explosions, a series of air guns or some active sonar. Non
c [m/s] c [m/s] c [m/s]
34 I. Sarić et