Life in the Open Ocean. Joseph J. Torres

Life in the Open Ocean - Joseph J. Torres


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illustration of typical oceanic oxygen concentrations."/>

      The ocean is sometimes characterized as a noisy place, though it may seem silent to scuba divers in the open ocean because most of the sounds are not discernible to human ears. Sound levels do vary considerably in the sea in the horizontal and vertical planes, and only a part is generated by the activities of humans. Detection of sound and other vibrations is a sensory modality shared by virtually all oceanic species. Some pelagic species, bottlenose dolphins, for example, use echolocation to locate prey, just as a bat does.

      Sound levels do not vary predictably in the ocean except in a general sense. Increasing distance from the crashing waves of a rocky shore will decrease the levels of ambient sound, as will increasing depth and distance from the wind‐induced turbulence of surface waters. However, the properties of sound do vary predictably, and a presentation of some basic concepts now will help with later discussions of hearing and mechanoreception in open‐ocean fauna. The physics of sound is quite complex; only the most rudimentary aspects will be covered in this book.

Schematic illustration of mechanical wave propagation.

      Source: Halliday and Resnick (1970), figure 16.1 (p. 301). Reproduced with the permission of John Wiley & Sons.

      The speed of sound in a medium is a function of the medium’s compressibility: the stiffer the medium, the faster sound will propagate through it. That is why the speed of sound in water is very much faster (4.3 times faster) than it is in air. However, to know if the speed of sound varies with depth in the ocean, we need to know a little more than that. We already know that the density of water does not increase much with increasing pressure. The ratio of the change in pressure on a volume of water (Δp) to the resulting change in volume of that water (−ΔV/V) is known as its bulk modulus of elasticity (“B”, Halliday and Resnick 1970, Denny 1993). B is positive because an increase in pressure results in a decrease in volume (or increase in density).

      (1.9)equation

      where Δp is the change in pressure, ΔV is the change in volume, p is the ambient pressure, and V is the volume at the original pressure. Put in a more empirical way, the same equation can be expressed as (Denny 1993):

      where p is the ambient pressure, p0 is the pressure at 1 atm, V is the volume at pressure p, and V0 is the volume at 1 atm. The bulk modulus of water is about 2 × 109 Pa depending on the temperature, which is a very considerable pressure. As mentioned earlier, the Challenger Deep at about 11 km of depth would yield a pressure of about 109 Pa, not nearly enough to double the density of water.

      The speed of sound through water is equal to the square root of the ratio of its bulk modulus to its density (Denny 1993).

      where c is the speed of sound, ρ is the density, and B is the bulk modulus.

Schematic illustration of velocity of sound in seawater as a function of depth. Maximum velocity at the bottom of the mixed layer. Minimum velocity at the base of the permanent thermocline.

      (1.12)equation

      where c is the speed of sound (m s−1), f is the frequency (cycles per second or Hertz (Hz)), and λ is the


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