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Weightlessness
*** Shopping-Tip: Weightlessness
Image:ZeroG.jpg right|thumb|375px|Astronauts on the International Space Station display an example of weightlessness. [[Michael Foale can be seen exercising in the foreground]]
'''Weightlessness''' is the experience (by people and objects) during
freefall, of having no
apparent weight. This condition is also known as '''microgravity''' (see below).
Weightlessness in common spacecraft is not due to an increased distance to the earth; the
acceleration due to
gravity at an altitude of 100 km is only 3% less than at the surface of the earth. Weightlessness means a zero
gee g-force or zero
apparent weight; acceleration is only due to gravity, as opposed to the cases where other forces are acting, including:
*standing on the ground, sitting in a chair on the ground, etc. (gravity is cancelled by the reaction force of the ground)
*flying in a plane (gravity is cancelled by the
Lift (force) lift the wings provide) - see below for special
trajectory trajectories which form an exception
*
atmospheric reentry,
landing on a
parachute: gravity is opposed by
atmospheric drag
*during an
orbital maneuver in a
spacecraft: the
rocket provides
thrust
The difference is that gravity acts directly on a person and other masses, just like on the vehicle, while forces like atmospheric drag and thrust first act on the vehicle, and through the vehicle on the person. In the first case the person and the vehicle floor are not pushed toward each other, while in the other cases they are.
Overview
What humans experience as weight is not actually the
force due to gravity (even though that is the technical definition of weight). What we feel as weight is actually the normal
Newton's_Laws_of_Motion#Newton.27s_third_law reaction force of the ground (or whatever surface we are in contact with) pushing upwards against us to counteract the force due to gravity, that is the
apparent weight.
For example, a wood block in a container in
free-fall experiences weightlessness. This is because there is no reaction to the wood block's weight from the container, as it is being pulled down with the same acceleration. The acceleration of the container equals the acceleration of the block, which equals the acceleration caused by gravity. When the container is at rest on the ground, however, the force on each piece of the block is not uniform. Because the block is not accelerating, there is also a force upward that arises because the block is a solid. Each horizontal cross section of the block experiences not only the force due to gravity on it, but also the weight of whatever portion of the block is above it. Part of feeling weight, then, is actually experiencing a pressure gradient within one's own body.
There is another aspect of the feeling of weight that a pressure gradient does not account for, an example of which is the way that our arms are pulled downward with respect to our body. This effect comes from the fact that something hanging is not supported directly via a pressure from the ground. In fact the effect is almost the exact opposite of a pressure gradient, it is a tension gradient. It occurs because each cross section of a hanging object, a rope for instance, must support the weight of every piece below it.
Hence, in short, weightlessness has nothing to do with whether we are under the influence of a gravitational force, but has to do with whether there are force gradients across our body. In free-fall, all parts of an object accelerate uniformly (assuming that there are no
tidal forces, which is true to a very good approximation for human-scale objects in earth orbit), and thus a human would experience no weight.
Microgravity
Image:Flame in space.gif right|thumb|180px|[[Candle flame in microgravity conditions.
NASA image.]]
The term
Microgravity environment microgravity is also used because weightlessness in e.g. a spaceship or other container is not perfect. Causes include:
*Gravity decreases 1
Parts per million ppm for every 3m increase in height.
*In a spaceship in orbit the required
centripetal force is higher at the upper side.
*Though very thin, there is some air at the level of the orbit, which causes deceleration due to friction.
The "weight" caused by the first two items (the
tidal force) is directed vertically away from the spacecraft, i.e. vertically away from Earth in the portion which is farther from Earth (or the body it is in orbit around) than the center of gravity of the spacecraft and vertically toward Earth for the rest. For the last item it is forward.
The microgravity symbol, ''µg'', was used on the insignia of the
Space Shuttle flight
STS-107, because this flight was devoted to microgravity research (see picture in that article).
NASA's KC-135 Reduced Gravity Aircraft
NASA's
KC-135 Vomit Comet Reduced Gravity Aircraft is based at
Lyndon B. Johnson Space Center and affectionately called the "
vomit comet". It is an airplane that NASA flies in 6 mile long
parabolic arcs, first climbing in altitude, then falling, in such a way that the flight path and speed correspond to that of an object without
propulsion and not experiencing air
friction. This is realised by propulsion and steering such that air friction is compensated and nothing else. The result is that people inside are not pushed towards the bottom or any other side of the plane, i.e. they are temporarily weightless, each time for a period of 25 seconds. Typically one flight lasts about two hours, in which 40 parabolas are flown.
Zero Gravity Corporation
The
Zero Gravity Corporation operates a modified
Boeing 727 which flies parabolic arcs similar to those of NASA's Reduced Gravity Aircraft. Flights may be purchased for both tourism and research purposes.
NASA's Zero-G Research Facility
NASA's [http://exploration.grc.nasa.gov/zero-g/ Zero-G Research Facility], located at the
Glenn Research Center in
Cleveland, Ohio, is a 145-meter vertical shaft, largely below the ground, with an integral vacuum drop chamber, in which an experiment vehicle can have a free fall for a duration of 5.18 seconds, falling a distance of 132 meters. The experiment vehicle is stopped in approximately 4.5 meters of pellets of expanded
polystyrene and experiences a peak deceleration rate of 65g.
Also at NASA Glenn is the 2.2 Second Drop Tower which is about 24 meters tall.
Humans cannot utilize these gravity shafts, as the deceleration experienced by the drop chamber is much too high to withstand.
Weightlessness in a spaceship
Weightlessness for a more extended period of time occurs in a
spaceship outside the earth's atmosphere, as long as no propulsion is applied, and that it is not rotating; orbiting the earth this is the case except when rockets are on for
orbital maneuvers, and until
atmospheric re-entry.
A
rocket ship that is accelerating by firing its rockets is a very different matter. Even if the rocket is accelerating uniformly, the force is applied to the back end of the rocket by the gas escaping out the back. This force must be transferred to each part of the ship through either pressure or tension, and thus weightlessness is not experienced.
Weightlessness in the centre of a planet
In the centre of a planet a person would feel weightless because the pull of the surrounding mass of the planet would cancel out. More generally, the gravitational force is zero ''everywhere'' within a
Hollow Earth hollow spherically symmetrical planet, by the
shell theorem.
Health effects
Following the establishment of orbiting stations that can be inhabited for long durations by humans, exposure to microgravity has been demonstrated to have some deleterious effects to health. Humans have evolved to be suited to life on the surface of the
Earth. When the constraint of gravity is removed, certain physiological systems begin to function to the detriment of the overall system.
The most common initial condition experienced by humans in weightless conditions is commonly known as
Space adaptation syndrome space sickness. The symptoms include general queasiness,
nausea,
Vertigo (medical) vertigo,
headaches,
lethargy,
vomiting, and an overall malaise. The first case was reported by
cosmonaut Gherman Titov in
1961. Since then roughly 45% of all people to experience free floating under zero gravity have also suffered from this condition. The duration of space sickness varies, but in no case has it lasted more than 72 hours. By that time the astronauts have grown accustomed to the new environment.
The most significant adverse effects of long-term weightlessness are
muscle atrophy and deterioration of the
skeleton; these effects can be minimized through a regimen of exercise. Other significant effects include fluid redistribution, a slowing of the
cardiovascular system, decreased production of
red blood cells, balance disorders, and a weakening of the
immune system. Lesser symptoms include weight loss, nasal congestion, sleep disturbance, excess
flatulence, and puffiness of the face. These effects are reversible upon return to
Earth.
Many of the conditions caused by exposure to weightlessness are similar to those resulting from aging. Scientists believe that studies of the detrimental effects of weightlessness could have medical benefits, such as a possible treatment for
osteoporosis and improved medical care for the bed-ridden and elderly.
See also
*
Artificial gravity
*
Human adaptation to space
*
uFluids@Home μFluids@Home—a
distributed computing project for the computer simulation of two-phase
fluid behavior in microgravity and
microfluidics problems
External links
-
Zero-G Research Facility, a
NASA facility for ground-based microgravity research
category:Gravity
de:Schwerelosigkeit
fr:Impesanteur
ko:ë¬´ì¤‘ë ¥
it:MicrogravitÃ
nl:Gewichtloosheid
pl:Nieważkość
pt:Microgravidade
ru:Ð?евеÑ?омоÑ?Ñ‚ÑŒ
*** Shopping-Tip: Weightlessness
