5/18/2023 0 Comments Speed of sound underwaterSimilarly, the difference in the stiffness between liquid mercury and solid iron are enough to overcome the greater density of the mercury to make sound propagate faster in the iron.The new idea is based on Soviet technology developed during the cold war.Ĭalled supercavitation, it envelopes a submerged vessel inside an air bubble to avoid problems caused by water drag.Ī Soviet supercavitation torpedo called Shakval was able to reach a speed of 370km/h or more - much faster than any other conventional torpedoes. The solid steel, despite being the same material with the same density as the slinky, is much stiffer, and therefore propagates waves very differently. Assuming the students could still move the mass with the same vigor, you would not be able to observe either a transverse or a longitudinal wave motion. Imagine repeating the experiment in that video with a solid steel bar of the same width and length. That slinky looks to be made of steel, but it is still very flexible, which is to say it is not stiff. Wave propagation is essentially a transfer of energy through a medium - that energy transfer is accomplished by a compression force at the molecular level.įor a macroscopic metaphor, imagine propagating a wave through a slinky. In a more general sense, different mediums have different responses to different forces. In a fluid the only non-zero stiffness is to volumetric deformation (a fluid does not sustain shear forces). Wikipedia summarizes this on the speed of sound section linked to above as: Simply put, gasses and liquids don't resist shearing forces.įor that reason, the shear modulus factors into the speed of sound in a solid, but not into the speed of sound in a liquid. Imagine trying to subject a liquid or a gas to a shearing force and it becomes clear that the shear modulus is meaningless for forms of matter other than solids. Specifically, it measures how a material responds to forces acting in opposite directions, as in friction holding a block in place or moving your hands away from each other to tear a piece of paper in half. Now the shear modulus is a measure of stiffness. ![]() ![]() Thus, the bulk modulus tells you how much the substance will shrink - that is, decrease in volume and increase in density - when subject to a given pressure. Uniform compression means the substance is experiencing equal pressure in all directions (as in atmospheric or underwater pressure). ![]() It is measured in pascals, which is the same unit for pressure. The bulk modulus is a measure of a substance's resistance to uniform compression. This is reflected in the equations for determining the speed of sound, most notably the presence of the bulk modulus and shear modulus in different places in the equations for sound in a solid and a liquid. There are more factors affecting the speed of sound in a substance other than the density of the medium. The following is my attempt to comprehend and explain the 'why' to the question. I don't want to detract from that treatment, and of course the Wikipedia articles we both draw from provide a broader treatment but an intuitive understanding of the 'why' has been equally helpful for me, in the past. John Rennie has provided an exact mathematical treatment of the equations behind the calculation of the speed of sound.
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