The 2009.12.26th edition
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Figure shows the relation of momenta when object Ma of minimum mass collides with heavy object Mb as elastic collision.
Ma that has flown from the direction of A collides at P point, and goes in the direction of B of symmetry with OC which is normal.
Mb hardly moves even if the momenta is gotten by the collision because it is heavy. Then, both laws of the energy conservation and the momentum conserving are considered. First of all, because Mb doesn't move, the received kinetic energy is none. And from the energy conservation law, Ma maintains same kinetic energy before and after collision. Threfore, absolute value of momenta of Ma before and after collision also doesn't change. Momenta is a vector with size and direction. Before and after the collision, momenta vectors are in the relation of parallelogram as shown in figure, and Mb receives a big momenta vector to the normal direction.
Here, vector AP and PB are momenta of Ma before and after the collision. Vector CP is a momenta that Mb receives by collision. It becomes AP=CP+PB from the law of conservation of momentum before and after collision.
Point aimed at in this collision:
As for Ma, kinetic energy is invariable, and the absolute value of momenta is also invariable.
Mb gets a big momenta without receiving energy. Though momenta becomes origin of force, there are no heating etc. by energy.
By the way, elastic collision seems to be basic of gravity theories of neutrino when mass of Mb is not infinity and is several digit larger than Ma.
la loses a part of kinetic energy, and absolute value of momenta also becomes small a little.
The received energy is generated in Mb. A big momenta is unchanged ..getting... Momenta becomes origin of force, and there are some heating etc. by energy, too.
In a word, about the direction going to M from space and the opposite direction going to space from M, the energy of neutrino of the latter is small. Quite a lot of similar collisions happen in all directions uniformly, and a gravity field toward M appears.
Reversely quadratic law
Particles hit against object M and particles spatter in all directions similarly. At a distant place from object M, concerning passing numbers of particles at unit area and unit time, gravity is strong where the number is large for near to object M but gravity is weak where the number is small for farther to object M. Here, the unit area is a part of surface of the sphere whose center is the position of object M. Intensity of gravity is proportional to numbers of those particles that hit and spatter. Particles hit against object M and particles spatter in all directions similarly. At the position of the distance R from object M, we think about the number of spattered particles. Passing number at unit area and unit time is in inverse proportion to the second power of the distance R. It ..a reversely quadratic law that is of gravity.. doesn't become it ..another...
Detection of gravity field
Next, it is assumed there are object S and another object M that raises gravity field. About the individual momentum vector that object S receives, the particle that comes from the direction of the object M loses energy a little by the collision and the absolute value of momentum vector has been small a little. Therefore, at the position of object S, valance of the momentum with direction collapses and gravitation generates. Only because one side changes a little, two big momentums for opposite mutually make big difference. That is, it is thought that a little difference of momentum between two particles is efficiently perceived at object S and object S changes the difference of momentum into gravitation in the gravity field.
It returns.
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