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Fluid Statics
By Andrew Zimmerman Jones
Fluid statics is the field of physics that involves the study of
fluids at rest.
Because these fluids are not in motion, that means they have
achieved a stable equilibrium state, so fluid statics is largely about
understanding these fluid equilibrium conditions.
When focusing on incompressible fluids (such as liquids) as
opposed to compressible fluids (such as most gases),
it is sometimes referred to as hydrostatics.
A fluid at rest does not undergo any sheer stress, and only
experiences the influence of the normal force of the surrounding fluid (and
walls, if in a container), which is the pressure.
(More on this below.) This form of equilibrium condition of a fluid is said to
be a hydrostatic condition.
Fluids that are not in a hydrostatic condition or at rest, and
are therefore in some sort of motion, fall under the other field of fluid
mechanics, fluid dynamics.
Major Concepts of Fluid Statics
Sheer stress vs. Normal stress
Consider a cross-sectional slice of a fluid. It is said to
experience a sheer stress if it is experiencing a stress that is coplanar, or a
stress that points in a direction within the plane.
Such a sheer stress, in a liquid, will cause motion within the
liquid. Normal stress, on the other hand, is a push into that cross-sectional
area.
If the area is against a wall, such as the side of a beaker,
then the cross-sectional area of the liquid will exert a force against the wall
(perpendicular to the cross section - therefore, not coplanar to it).
The liquid exerts a force against the wall and the wall exerts a
force back, so there is net force and therefore no change in motion.
The concept of a normal force may be familiar from early in
studying physics, because it shows up a lot in working with and analyzing free-body
diagrams.
When something is sitting still on the ground, it pushes down
toward the ground with a force equal to its weight.
The ground, in turn, exerts a normal force back on the bottom of
the object. It experiences the normal force, but the normal force doesn't
result in any motion.
A sheer force would be if someone shoved on the object from the
side, which would cause the object to move so long that it can overcome the
resistance of friction.
A force coplanar within a liquid, though, isn't going to be
subject to friction, because there isn't friction between molecules of a fluid.
That's part of what makes it a fluid rather than two solids.
But, you say, wouldn't that mean that the cross section is being
shoved back into the rest of the fluid? And wouldn't that mean that it moves?
This is an excellent point. That cross-sectional sliver of fluid
is being pushed back into the rest of the liquid, but when it does so the rest
of the fluid pushes back.
If the fluid is incompressible, then this pushing isn't going to
move anything anywhere. The fluid is going to push back and everything will
stay still.
(If compressible, there are other considerations, but let's keep
it simple for now.)
Pressure
All of these tiny cross sections of liquid pushing against each
other, and against the walls of the container, represent tiny bits of force,
and all of this force results in another important physical property of the
fluid: the pressure.
Instead of cross-sectional areas, consider the fluid divided up
into tiny cubes.
Each side of the cube is being pushed on by the surrounding
liquid (or the surface of the container, if along the edge) and all of these
are normal stresses against those sides.
The incompressible fluid within the tiny cube cannot compress
(that's what "incompressible" means, after all), so there is no
change of pressure within these tiny cubes.
The force pressing on one of these tiny cubes will be normal
forces that precisely cancel out the forces from the adjacent cube surfaces.
This cancellation of forces in various directions is of the key
discoveries in relation to hydrostatic pressure, known as Pascal's Law after
the brilliant French physicist and mathematician Blaise Pascal (1623-1662).
This means that the pressure at any point is the same in all
horizontal directions, and therefore that the change in pressure between two
points will be proportional to the difference in height.
Density
Another key concept in understanding fluid statics is the density of
the fluid.
It figures into the Pascal's Law equation, and each fluid (as
well as solids and gases) have densities that can be determined experimentally.
Here are a handful of common densities.
Density is the mass per unit volume. Now think about various
liquids, all split up into those tiny cubes I mentioned earlier.
If each tiny cube is the same size, then differences in density
means that tiny cubes with different densities will have different amount of
mass in them.
A higher-density tiny cube will have more "stuff" in
it than a lower-density tiny cube.
The higher-density cube will be heavier than the lower-density
tiny cube, and will therefore sink in comparison to the lower-density tiny
cube.
So if you mix two fluids (or even non-fluids) together, the
denser parts will sink that the less dense parts will rise.
This is also evident in the principle of buoyancy,
that explains how displacement of liquid results in an upward force, if you
remember your Archimedes.
If you pay attention to the mixing of two fluids while it's
happening, such as when you mix oil and water, there'll be a lot of fluid
motion, and that would covered by fluid dynamics.
But once the fluid reaches equilibrium, you'll have fluids of
different densities that have settled into layers, with the highest density
fluid forming the bottom layer, up until you reach the lowest density fluid
on the top layer.
An example of this is shown on the graphic on this page, where
fluids of different types have differentiated themselves into stratified layers
based on their relative densities.
Andrew
Zimmerman Jones
Math
and Physics Expert
Education
M.S.,
Mathematics Education, Indiana University
B.A.,
Physics, Wabash College
Introduction
Academic
researcher, educator, and writer with 23 years of experience in physical
sciences
Works
at Indiana Department of Education as senior assessment specialist in
mathematics
Co-author
of String Theory For Dummies
Member
of the National Association of Science Writers
Experience
Andrew
Zimmerman Jones is a former writer for ThoughtCo who contributed nearly 200
articles for more than 10 years. His topics ranged from the definition of
energy to vector mathematics. Andrew is a dedicated educator; and he uses his
background in the physical sciences, educational assessment, writing, and
communications to advance that mission.
Andrew
is co-author of String Theory For Dummies, which discusses the basic concepts
of this controversial approach. String theory tries to explain certain
phenomena that are not currently explainable under the standard quantum physics
model.
Since
2018, Andrew has worked at the Indiana Department of Education as a senior
assessment specialist in mathematics; prior to which he served as a senior
assessment editor at CTB/McGraw Hill for 10 years. In addition, Andrew was a
researcher at Indiana University's Cyclotron Facility. He is a member of the
National Association of Science Writers.
Education
Andrew
Zimmerman Jones received an M.S. in Mathematics Education from Indiana
University–Purdue and a B.A. in Physics from Wabash College.
Awards
and Publications
String
Theory For Dummies (Wiley–For Dummies Series, 2009)
Harold
Q. Fuller Prize in Physics (Wabash College, 1998)
ThoughtCo
and Dotdash
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