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Revision as of 11:48, 30 May 2009 by FDT (talk | contribs) (generalizing the introduction)(diff) ← Previous revision | Latest revision (diff) | Newer revision → (diff)In everyday understanding, centrifugal force (from Latin centrum "center" and fugere "to flee") represents the effects of inertia that arise in connection with rotation and which are experienced as an outward force away from the center of rotation. In modern science, it can apply to an inertial force that appears when Newton's laws are expressed in polar coordinates , fictitious forces that are observed from a rotating frame of reference, or to Newton's reactive centrifugal force. This article summarizes the several ideas surrounding the concept of centrifugal force.
Fictitious force in a rotating reference frame
Main article: Centrifugal force (rotating reference frame)Nowadays, centrifugal force is most commonly introduced as a force that is observed in a rotating reference frame, and referred to as a fictitious or inertial force (a description that must be understood as a technical usage of these words that means only that the force is not present in a stationary or inertial frame). Centrifugal force is zero when the rate of rotation of the reference frame is zero, independent of the motions of objects in the frame.
If objects are seen as moving within a rotating frame, this movement results in another fictitious force, the Coriolis force; and if the rate of rotation of the frame is changing, a third fictitious force, the Euler force is experienced. Together, these three fictitious forces allow for the creation of correct equations of motion in a rotating reference frame.
Reactive centrifugal force
Main article: Reactive centrifugal forceA reactive centrifugal force is the reaction force to a centripetal force. A mass undergoing curved motion, such as circular motion, constantly accelerates toward the axis of rotation. This centripetal acceleration is provided by a centripetal force, which is exerted on the mass by some other object. In accordance with Newton's Third Law of Motion, the mass exerts an equal and opposite force on the object. This is the "real" or "reactive" centrifugal force: it is directed away from the center of rotation, and is exerted by the rotating mass on the object that originates the centripetal acceleration.
The concept of the reactive centrifugal force is used often in mechanical engineering sources that deal with internal stresses in rotating solid bodies. Newton's reactive centrifugal force still appears in some sources, and is often referred to as the centrifugal force rather than as the reactive centrifugal force.
Reactive vs. fictitious force
The table below compares various facets of the "reactive force" and "fictitious force" concepts of centrifugal force.
Reactive centrifugal force | Fictitious centrifugal force | |
---|---|---|
Reference frame |
Any | Rotating frames |
Exerted by |
Bodies moving in circular paths |
Acts as if emanating from the rotation axis, but no real source |
Exerted upon |
The object(s) causing the curved motion, not upon the body in curved motion |
All bodies, moving or not; if moving, Coriolis force also is present |
Direction | Opposite to the centripetal force causing curved path |
Away from rotation axis, regardless of path of body |
Analysis | Kinematic: related to centripetal force |
Kinetic: included as force in Newton's laws of motion |
Centrifugal force and absolute rotation
Can absolute rotation be detected? In other words, can one decide whether an observed object is rotating or if it is you, the observer that is rotating? Newton suggested two experiments to resolve this problem. One is the effect of centrifugal force upon the shape of the surface of water rotating in a bucket. The second is the effect of centrifugal force upon the tension in a string joining two spheres rotating about their center of mass. A related third suggestion was that rotation of a sphere (such as a planet) could be detected from its shape (or "figure"), which is formed as a balance between containment by gravitational attraction and dispersal by centrifugal force.
Rotating bucket
See also: Bucket argumentNewton suggested the shape of the surface of the water indicates the presence or absence of absolute rotation relative to the fixed stars: rotating water has a curved surface, still water has a flat surface. Because rotating water has a concave surface, if the surface you see is concave, and the water does not seem to you to be rotating, then you are rotating with the water.
Centrifugal force is needed to explain the concavity of the water in a co-rotating frame of reference (one that rotates with the water) because the water appears stationary in this frame, and so should have a flat surface. Thus, observers looking at the stationary water need the centrifugal force to explain why the water surface is concave and not flat. The centrifugal force pushes the water toward the sides of the bucket, where it piles up deeper and deeper, Pile-up is arrested when any further climb costs as much work against gravity as is the energy gained from the greater centrifugal force at larger radius.
If you need a centrifugal force to explain what you see, then you are rotating. Newton's conclusion was that rotation is absolute.
Other thinkers suggest that pure logic implies only relative rotation makes sense. For example, Bishop Berkeley and Ernst Mach (among others) suggested that it is relative rotation with respect to the fixed stars that matters, and rotation of the fixed stars relative to an object has the same effect as rotation of the object with respect to the fixed stars. Newton's arguments do not settle this issue; his arguments may be viewed, however, as establishing centrifugal force as a basis for an operational definition of what we actually mean by absolute rotation.
Rotating spheres
See also: Rotating spheresNewton also proposed another experiment to measure one's rate of rotation: using the tension in a cord joining two spheres rotating about their center of mass. Non-zero tension in the string indicates rotation of the spheres, whether or not the observer thinks they are rotating. This experiment is simpler than the bucket experiment in principle, because it need not involve gravity.
Beyond a simple "yes or no" answer to rotation, one may actually calculate one's rotation. To do that, one takes one's measured rate of rotation of the spheres and computes the tension appropriate to this observed rate. This calculated tension then is compared to the measured tension. If the two agree, one is in a stationary (non-rotating ) frame. If the two do not agree, to obtain agreement, one must include a centrifugal force in the tension calculation; for example, if the spheres appear to be stationary, but the tension is non-zero, the entire tension is due to centrifugal force. From the necessary centrifugal force, one can determine one's speed of rotation; for example, if the calculated tension is greater than measured, one is rotating in the sense opposite to the spheres, and the larger the discrepancy the faster this rotation.
The centrifugal force is not simply cerebral, but actually is experienced by the rotating observer. That is, forces experienced by the rotating observer are equally real, whether their origin is fundamental or simply in the rotation of the observer.
Figure of the Earth
See also: Clairaut's theorem and Figure of the EarthIn a similar fashion, if we did not know the Earth rotates about its axis, we could infer this rotation from the centrifugal force needed to account for the bulging observed at its equator.
In his Principia, Newton proposed the shape of the rotating Earth was that of a homogeneous ellipsoid formed by an equilibrium between the gravitational force holding it together and the centrifugal force pulling it apart. The Earth's surface is an equipotential, that is, no work is done moving upon the Earth's surface, either against gravity or against centrifugal force. Based upon this equilibrium, Newton determined a flattening expressed by the ratio of diameters: 230 to 229. A modern measurement of the Earth's oblateness leads to an equatorial radius of 6378.14 km and a polar radius of 6356.77 km, about 1/10% less oblate than Newton's estimate. The precise extent of oblateness in response to a centrifugal force requires an understanding of the make-up of the planet, not only today but during its formation.
History of conceptions of centrifugal and centripetal forces
Christiaan Huygens coined the term "centrifugal force" (vis centrifuga) in his 1673 Horologium Oscillatorium on pendulums, and Newton coined the term "centripetal force" (vis centripita) in his discussions of gravity in his 1684 De Motu Corpurum. Gottfried Leibniz as part of his 'solar vortex theory' conceived of centrifugal force as a real outward force which is induced by the circulation of the body upon which the force acts. The inverse cube law centrifugal force appears in an equation representing planetary orbits, including non-circular ones, as Leibniz described in his 1689 Tentamen de motuum coelestium causis. Leibniz's equation is still used today to solve planetary orbital problems, although the 'solar vortex theory' is no longer used as its basis.
There is evidence that Isaac Newton originally conceived of a similar approach to centrifugal force as Leibniz, though he seems to have changed his position at some point. When Leibniz produced his equation for planetary orbits in which the centrifugal force appeared as an outward inverse cube law force in the radial direction , Newton objected to this equation on the grounds that it allowed for the centrifugal force to have a different value from the centripetal force, despite the fact that Newton himself appears to have previously supported an approach similar to that of Leibniz. But Newton was now arguing on the basis of his third law of motion, that the centrifugal force and the centripetal force must constitute an equal and opposite action-reaction pair.
It wasn't until the latter half of the 18th century that the modern "fictitious force" understanding of the centrifugal force as a pseudo-force artifact of rotating reference frames took shape. In a 1746 memoir by Daniel Bernoulli, the "idea that the centrifugal force is fictitious emerges unmistakably." Bernoulli, in seeking to describe the motion of an object relative to an arbitrary point, showed that the magnitude of the centrifugal force depended on which arbitrary point was chosen. In other words, the centrifugal force depended on the reference frame of the observer, as opposed to other forces which depended only on the properties of the objects involved in the problem and were independent of the frame. Also in the second half of the 18th century, Joseph Louis Lagrange in his Mécanique Analytique explicitly stated that the centrifugal force depends on the rotation of a system of perpendicular axes. In 1835, Gaspard-Gustave Coriolis analyzed arbitrary motion in rotating systems, specifically in relation to waterwheels. He coined the phrase "compound centrifugal force" for a term which bore a similar mathematical expression to that of centrifugal force, albeit that it was multiplied by a factor of two. The force in question was perpendicular to both the velocity of an object relative to a rotating frame of reference and the axis of rotation of the frame. Compound centrifugal force eventually came to be known as the Coriolis Force.
The modern interpretation is that centrifugal force in a rotating reference frame is a pseudo-force that appears in equations of motion in rotating frames of reference, to explain effects of inertia as seen in such frames. Leibniz's centrifugal force may be understood as an application of this conception, as a result of his viewing the motion of a planet along the radius vector, that is, from the standpoint of a special reference frame rotating with the planet. Occasionally, when Leibniz's radial equation is used in central force problems, the full rotating reference frame transformation is not explicitly stated, but is implicit in the derivation.
See also
The concept of centrifugal force in its more technical aspects introduces several additional topics:
- Reference frames, which compare observations by observers in different states of motion. Among the many possible reference frames the inertial frame of reference are singled out as the frames where physical laws take their simplest form. In this context, physical forces are divided into two groups: real forces that originate in real sources, like electrical force originates in charges, and
- Fictitious forces that do not so originate, but originate instead in the motion of the observer. Naturally, forces that originate in the motion of the observer vary with the motion of the observer, and in particular vanish for some observers, namely those in inertial frames of reference.
Centrifugal force has played a key role in debates over relative versus absolute rotation. These historic arguments are found in the articles:
- Bucket argument: The historic example proposing that explanations of the observed curvature of the surface of water in a rotating bucket are different for different observers, allowing identification of the relative rotation of the observer. In particular, rotating observers must invoke centrifugal force as part of their explanation, while stationary observers do not.
- Rotating spheres: The historic example proposing that the explanation of the tension in a rope joining two spheres rotating about their center of gravity are different for different observers, allowing identification of the relative rotation of the observer. In particular, rotating observers must invoke centrifugal force as part of their explanation of the tension, while stationary observers do not.
The analogy between centrifugal force (sometimes used to create artificial gravity) and gravitational forces led to the equivalence principle of general relativity.
References
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- See cartoon: XKCD demonstrates the life and death importance of centrifugal force.
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has extra text (help) - Alexander Winchell (1888). World-life; Or, Comparative Geology. SC Griggs & Co. p. 425.
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ignored (help) - Rizzi & Ruggiero 2004, p. 272.
- Rindler 2006, pp. 7-8.
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