Difference between revisions of "GFDL:Lagrangian point"

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(Made it explicit that the bodies are rotating about each other. The massive bodies need not have different masses. Other small re-orderings and simplifications.)
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[[de:Lagrange-Punkt]] [[fr:Point de Lagrange]]
 
[[de:Lagrange-Punkt]] [[fr:Point de Lagrange]]
In [[Lagrangian mechanics]], a '''Lagrangian point''' (or '''Lagrange point''', or simply '''L-point''') is one of five positions in space where the [[gravity|gravitational field]]s of two bodies of substantial but differing [[mass]] combine to form a point at which a third body of negligible mass would be stationary relative to the two bodies.  Bodies at the L-point will not move relative to the parent bodies if they are not perturbed by other gravitational forces. They are sometimes also referred to as ''libration points''.
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In [[Lagrangian mechanics]], a '''Lagrangian point''' (also '''Lagrange point''', '''L-point''', or '''libration point''') is one of five positions in space where the [[gravity|gravitational field]]s of two massive bodies rotating about each other combine to form a point at which a third body of negligible mass would be stationary relative to the two bodies.  Bodies at the L-points will not move relative to the parent bodies if they are not perturbed by other gravitational forces. That is, the system of bodies will rotate about a common axis.
  
 
The five points are labelled and defined as follows:
 
The five points are labelled and defined as follows:
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On the line defined by the two large masses, and between them.
 
On the line defined by the two large masses, and between them.
  
'''Example:''' An object which orbits the [[Sun]] more closely than the [[Earth]] does would normally have a shorter orbital period than the Earth, but that ignores the effect of the Earth's own gravitational pull. If the object is directly between the Earth and the Sun, then the effect of the Earth's gravity is to weaken the force pulling the object towards the Sun, and therefore increase the orbital period of the object. The closer to Earth the object is, the greater this effect is. At a certain point, called the L<sub>1</sub> point, the orbital period of the object becomes exactly equal to the Earth's orbital period. The [[Solar and Heliospheric Observatory]] (SOHO) ( http://sohowww.nascom.nasa.gov/ ), for example, is stationed in a halo orbit around the Sun-Earth L<sub>1</sub> point.
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'''Example:''' An object which orbits the [[Sun]] more closely than the [[Earth]] would normally have a shorter orbital period than the Earth, but that ignores the effect of the Earth's own gravitational pull. If the object is directly between the Earth and the Sun, then the effect of the Earth's gravity is to weaken the force pulling the object towards the Sun, and therefore increase the orbital period of the object. The closer to Earth the object is, the greater this effect is. At the L<sub>1</sub> point, the orbital period of the object becomes exactly equal to the Earth's orbital period. The [[Solar and Heliospheric Observatory]] (SOHO) ( http://sohowww.nascom.nasa.gov/ ), for example, is stationed in a halo orbit around the Sun-Earth L<sub>1</sub> point.
  
 
==L<sub>2</sub>==
 
==L<sub>2</sub>==
 
On the line defined by the two large masses, and beyond the smaller of the two.  
 
On the line defined by the two large masses, and beyond the smaller of the two.  
  
'''Example:''' A similar effect occurs on the other side of the Earth, further away from the Sun, where the orbital period of an object would normally be greater than that of the Earth. The extra pull of the Earth's gravity decreases the orbital period of the object, and at the L<sub>2</sub> point that orbital period becomes equal to the Earth's.
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'''Example:''' A similar effect occurs on the other side of the Earth, further away from the Sun, where the orbital period of an object would normally be greater than that of the Earth. The extra pull of the Earth's gravity decreases the orbital period of the object, and at the L<sub>2</sub> point that orbital period becomes equal to the Earth's.  The proposed [[James Webb Space Telescope]] will be placed at the Sun-Earth L<sub>2</sub>.
  
 
==L<sub>3</sub>==
 
==L<sub>3</sub>==
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==L<sub>5</sub>==
 
==L<sub>5</sub>==
 
At the third point of an equilateral triangle with the base of the line defined by the two masses, such that the point is behind the smaller mass in its orbit around the larger mass.
 
At the third point of an equilateral triangle with the base of the line defined by the two masses, such that the point is behind the smaller mass in its orbit around the larger mass.
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L<sub>4</sub> and L<sub>5</sub> are sometimes called ''triangular Lagrange points'' or ''Trojan points''.
  
 
'''Example:''' The L<sub>4</sub> and L<sub>5</sub> points lie 60 [[degree]]s ahead of and 60 degrees behind the Earth in its orbit around the Sun. Unlike the other Lagrangian points, these points are resistant to perturbation, and therefore objects tend to accumulate around these points.
 
'''Example:''' The L<sub>4</sub> and L<sub>5</sub> points lie 60 [[degree]]s ahead of and 60 degrees behind the Earth in its orbit around the Sun. Unlike the other Lagrangian points, these points are resistant to perturbation, and therefore objects tend to accumulate around these points.
 
The latter two types of Lagrange points are sometimes called ''triangular Lagrange points'' or ''Trojan points''.
 
  
 
<center>[[image:lagrangepoint1.png]]</center>
 
<center>[[image:lagrangepoint1.png]]</center>
  
In practice the stability of Lagrange points is not real, as there are more than three bodies in the universe. Additional gravitational pulls from elsewhere cause objects to move away from the point. The first three Langrangian points are stable only in the plane perpendicular to the line between the two bodies. This can be seen most easily by considering the L<sub>1</sub> point. A test mass displaced perpendicularly from the central line would feel a force pulling it back towards the equilibrium point. This is because the lateral components of the two masses' gravity would add to produce this force, whereas the components along the axis between them would balance out. On the other hand, if an object located at the L<sub>1</sub> point drifted closer to one of the masses, the gravitational attraction it felt from that mass would be greater, and it would be pulled closer. (The pattern is very similar to that of [[tidal force|tidal forces]].)
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In practice the stability of Lagrange points is not real, as there are more than three bodies in the universe. Additional gravitational pulls from elsewhere cause objects to move away from the point. The first three Lagrangian points are stable only in the plane perpendicular to the line between the two bodies. This can be seen most easily by considering the L<sub>1</sub> point. A test mass displaced perpendicularly from the central line would feel a force pulling it back towards the equilibrium point. This is because the lateral components of the two masses' gravity would add to produce this force, whereas the components along the axis between them would balance out. On the other hand, if an object located at the L<sub>1</sub> point drifted closer to one of the masses, the gravitational attraction it felt from that mass would be greater, and it would be pulled closer. (The pattern is very similar to that of [[tidal force|tidal forces]].)
  
However, in the particular case of the L<sub>4</sub> and L<sub>5</sub> points, [[Coriolis force]]s begin to act on an object moving away from the point, and bend the object's path into a stable, [[kidney bean]]-shaped (from the viewpoint of the smaller mass) orbit around the point. This arrangement is stable (cf [[attractor]]). In the [[Jupiter (planet)|Jupiter]]-Sun system several thousand [[asteroid|asteroids]], collectively referred to as [[Trojan asteroid|Trojan asteroids]], are in such orbits. Other bodies can be found in the Sun-[[Saturn (planet)|Saturn]], Sun-[[Mars (planet)|Mars]], Jupiter-Jupiter Satellite, and Saturn-Saturn Satellite systems. There are no known large bodies in the Sun-Earth system's Trojan points, but clouds of dust surrounding the L<sub>4</sub> and L<sub>5</sub> points were discovered in the [[1950s]]. Clouds of dust, fainter than the notoriously difficult [[gegenschein]], are also present in the L<sub>4</sub> and L<sub>5</sub> of the Earth-Luna system.
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However, in the particular case of L<sub>4</sub> and L<sub>5</sub>, [[Coriolis force]]s act on an object moving away from the point, and bend the object's path into a stable, [[kidney bean]]-shaped (from the viewpoint of the smaller mass) orbit around the point. This arrangement is stable (cf [[attractor]]). In the [[Jupiter (planet)|Jupiter]]-Sun system several thousand [[asteroid|asteroids]], collectively referred to as [[Trojan asteroid|Trojan asteroids]], are in such orbits. Other bodies can be found in the Sun-[[Saturn (planet)|Saturn]], Sun-[[Mars (planet)|Mars]], Jupiter-Jupiter Satellite, and Saturn-Saturn Satellite systems. There are no known large bodies in the Sun-Earth system's Trojan points, but clouds of dust surrounding the L<sub>4</sub> and L<sub>5</sub> points were discovered in the [[1950s]]. Clouds of dust, fainter than the notoriously difficult [[gegenschein]], are also present in the L<sub>4</sub> and L<sub>5</sub> of the Earth-Luna system.
  
 
The Earth's companion object [[3753 Cruithne]] is in a somewhat Trojan-like orbit around the Earth, but not in the same manner as a true Trojan.  It has a regular solar orbit that is bumped at times by Earth. When the asteroid approaches Earth, the asteroid takes orbital energy from Earth and moves into a larger, higher energy orbit. When the asteroid (in a larger and slower orbit) is caught up by Earth, Earth takes the energy back and so the asteroid falls into a smaller, faster orbit and eventually catches Earth to begin the cycle anew. [[Epimetheus (moon)|Epimetheus]] and [[Janus (moon)|Janus]], satellites of Saturn, have a similar relationship, though they are of similar masses and so actually exchange orbits periodically. Another similar configuration is known as [[orbital resonance]], in which orbiting bodies tend to have periods of a simple integer ratio, due to their interaction.  
 
The Earth's companion object [[3753 Cruithne]] is in a somewhat Trojan-like orbit around the Earth, but not in the same manner as a true Trojan.  It has a regular solar orbit that is bumped at times by Earth. When the asteroid approaches Earth, the asteroid takes orbital energy from Earth and moves into a larger, higher energy orbit. When the asteroid (in a larger and slower orbit) is caught up by Earth, Earth takes the energy back and so the asteroid falls into a smaller, faster orbit and eventually catches Earth to begin the cycle anew. [[Epimetheus (moon)|Epimetheus]] and [[Janus (moon)|Janus]], satellites of Saturn, have a similar relationship, though they are of similar masses and so actually exchange orbits periodically. Another similar configuration is known as [[orbital resonance]], in which orbiting bodies tend to have periods of a simple integer ratio, due to their interaction.  

Revision as of 11:57, 21 January 2004

de:Lagrange-Punkt fr:Point de Lagrange In Lagrangian mechanics, a Lagrangian point (also Lagrange point, L-point, or libration point) is one of five positions in space where the gravitational fields of two massive bodies rotating about each other combine to form a point at which a third body of negligible mass would be stationary relative to the two bodies. Bodies at the L-points will not move relative to the parent bodies if they are not perturbed by other gravitational forces. That is, the system of bodies will rotate about a common axis.

The five points are labelled and defined as follows:

L1

On the line defined by the two large masses, and between them.

Example: An object which orbits the Sun more closely than the Earth would normally have a shorter orbital period than the Earth, but that ignores the effect of the Earth's own gravitational pull. If the object is directly between the Earth and the Sun, then the effect of the Earth's gravity is to weaken the force pulling the object towards the Sun, and therefore increase the orbital period of the object. The closer to Earth the object is, the greater this effect is. At the L1 point, the orbital period of the object becomes exactly equal to the Earth's orbital period. The Solar and Heliospheric Observatory (SOHO) ( http://sohowww.nascom.nasa.gov/ ), for example, is stationed in a halo orbit around the Sun-Earth L1 point.

L2

On the line defined by the two large masses, and beyond the smaller of the two.

Example: A similar effect occurs on the other side of the Earth, further away from the Sun, where the orbital period of an object would normally be greater than that of the Earth. The extra pull of the Earth's gravity decreases the orbital period of the object, and at the L2 point that orbital period becomes equal to the Earth's. The proposed James Webb Space Telescope will be placed at the Sun-Earth L2.

L3

On the line defined by the two large masses, and beyond the larger of the two.

Example: A third Lagrangian point, L3, exists on the opposite side of the Sun, a little further away from the Sun than the Earth is, where the combined pull of the Earth and Sun again causes the object to orbit with the same period as the Earth. When used with the Sun and the Earth as the two masses, the L3 point was a popular place to put an "Anti-Earth" in pulp science fiction and comic books.

L4

At the third point of an equilateral triangle with the base of the line defined by the two masses, such that the point is ahead of the smaller mass in its orbit around the larger mass.

L5

At the third point of an equilateral triangle with the base of the line defined by the two masses, such that the point is behind the smaller mass in its orbit around the larger mass.

L4 and L5 are sometimes called triangular Lagrange points or Trojan points.

Example: The L4 and L5 points lie 60 degrees ahead of and 60 degrees behind the Earth in its orbit around the Sun. Unlike the other Lagrangian points, these points are resistant to perturbation, and therefore objects tend to accumulate around these points.

File:Lagrangepoint1.png

In practice the stability of Lagrange points is not real, as there are more than three bodies in the universe. Additional gravitational pulls from elsewhere cause objects to move away from the point. The first three Lagrangian points are stable only in the plane perpendicular to the line between the two bodies. This can be seen most easily by considering the L1 point. A test mass displaced perpendicularly from the central line would feel a force pulling it back towards the equilibrium point. This is because the lateral components of the two masses' gravity would add to produce this force, whereas the components along the axis between them would balance out. On the other hand, if an object located at the L1 point drifted closer to one of the masses, the gravitational attraction it felt from that mass would be greater, and it would be pulled closer. (The pattern is very similar to that of tidal forces.)

However, in the particular case of L4 and L5, Coriolis forces act on an object moving away from the point, and bend the object's path into a stable, kidney bean-shaped (from the viewpoint of the smaller mass) orbit around the point. This arrangement is stable (cf attractor). In the Jupiter-Sun system several thousand asteroids, collectively referred to as Trojan asteroids, are in such orbits. Other bodies can be found in the Sun-Saturn, Sun-Mars, Jupiter-Jupiter Satellite, and Saturn-Saturn Satellite systems. There are no known large bodies in the Sun-Earth system's Trojan points, but clouds of dust surrounding the L4 and L5 points were discovered in the 1950s. Clouds of dust, fainter than the notoriously difficult gegenschein, are also present in the L4 and L5 of the Earth-Luna system.

The Earth's companion object 3753 Cruithne is in a somewhat Trojan-like orbit around the Earth, but not in the same manner as a true Trojan. It has a regular solar orbit that is bumped at times by Earth. When the asteroid approaches Earth, the asteroid takes orbital energy from Earth and moves into a larger, higher energy orbit. When the asteroid (in a larger and slower orbit) is caught up by Earth, Earth takes the energy back and so the asteroid falls into a smaller, faster orbit and eventually catches Earth to begin the cycle anew. Epimetheus and Janus, satellites of Saturn, have a similar relationship, though they are of similar masses and so actually exchange orbits periodically. Another similar configuration is known as orbital resonance, in which orbiting bodies tend to have periods of a simple integer ratio, due to their interaction.

The Saturnian moon Tethys has two smaller moons in its L4 and L5 points, Telesto and Calypso. The Saturnian moon Dione has the moon Helene in its L4 point.

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